RU2513805C1 - Method to increase permeability of coal bed via wells drilled from mines - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method includes creation of a cavity in a coal bed by means of cyclic increase and decrease of liquid pressure in a borehole and exposing the bed to low-frequency pressure pulses as liquid pressure in the well increases. Cyclic increase and decrease of liquid pressure is created via a hydraulic multiplier installed on the head, besides, the piston of the smaller area of the working surface of the hydraulic multiplier acts at liquid filling the borehole, the piston of larger area of the working surface is exposed to compressed gas, the volume of liquid portion injected into the bed is determined by the length of travel of the hydraulic multiplier, pressure and speed of liquid injection into the bed is adjusted due to pressure of compressed gas, the ratio of areas of working surfaces of the pistons of the hydraulic multiplier and speed of compressed gas injection.

EFFECT: development of a net of bed cracks around a well.

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Description

The present invention relates to the mining industry and can be used for the degassing of coal seams in order to increase the safety of work in mines, as well as for the extraction of methane for use in industry from coal seams through holes drilled from a mine.

A known method of downhole hydraulic mining of minerals (Patent No. 2014456 publ. 1994.06.15), including drilling wells, installing an elastic oscillation generator in the interval of the reservoir, supplying an energy component, delivering minerals through pipes to the surface and intensifying the production process by excitation in the well elastic pulsed pressure waves, the energy spectra of which contain rock liquefaction frequencies, and the excess pressure at the wave front exceeds the value required for their tick Sotropnoy softening.

However, vibration allows only microcracks to be created. For effective softening and destruction of the rock due to the vibration created by the generator of elastic vibrations, it is necessary that the reservoir contains stresses created by natural processes or artificially.

A known method of rock washing (Patent No. 2014457 publ. 1994.06.15) by supplying an intermittent stream of liquid under pressure, moreover, the interruption of a stream of liquid is carried out with a frequency equal to the resonant oscillation frequency of the developed rocks.

However, the erosion of the rock by a pulsating liquid stream is carried out only in the immediate vicinity of the bottom-hole zone; the creation of cracks in the formation thickness is possible when oscillations are generated and transmitted through the dense solid and liquid phases of the formation.

There is a method of vibration-borehole impact on a coal mass to reduce emissions (Patent No. 2068962 publ. 1996.11.10), which includes drilling wells in the host rock formation, installing vibration sources in them and subsequent vibration processing of the coal mass, drilling wells in the rock shifting the formation is carried out with the introduction they are placed in a particularly hazardous coal mass at a distance from the bottom not closer than a predetermined value; after vibration processing of the coal mass, the wells are conventionally divided into two groups and coal is degassed through them th array.

However, vibration allows only microcracks to be created. For effective softening and rock destruction due to vibration, the presence of stresses created by natural processes or artificially in the reservoir is necessary.

A known method of hydraulic treatment of a coal seam (Patent No. 2188322 publ. 2002.08.27), including pumping the working fluid into the coal seam in the mode of hydraulic separation, followed by the discharge of the wellhead pressure of the fluid to atmospheric pressure, creates hydraulic shock when the fluid flows freely from the well, cyclically blocking the flow.

However, the application of the method contributes to the creation of cracks due to the use of constant pressure, as well as hydraulic shocks during the free flow of fluid from the well with the formation of cracks, mechanisms of crack development by repression pressure pulses are not used.

A known method of hydraulic processing of a coal seam (Patent No. 2298650 publ. 2007.05.10), which includes pumping fluid into the reservoir in a filtration mode, then creating hydraulic shocks when the wellhead pressure is released to atmospheric pressure, followed by fluid outflow from the well and with the accumulation of hydraulic energy the flow created by the injection pump for hydraulic disintegration of the formation along the directions of the formed cracks. These processes are repeated until hydroprocessing design areas around the well are formed in the reservoirs.

However, the application of the method contributes to the creation of short-term hydraulic shocks with the formation of cracks during discharge of wellhead pressure; mechanisms of crack development by repression pressure pulses are not used.

A known method of intensifying the production of natural gas from coal seams (Patent No. 2343275 publ. 2009.01.10), adopted as a prototype and including creating a cavity in the coal seam by cyclically increasing and decreasing the pressure of the liquid in the well and exposing the formation to low-frequency high-pressure pressure pulses with increasing fluid pressure in the well.

However, when slowly increasing pressure is applied, a single crack usually forms, developing in the zone of least strength. When the pressure is removed, the crack closes, preventing the formation permeability from increasing. Sources of vibration located at the depth of the bed due to size limitations have low power.

The technical result of the invention is the development of a network of formation cracks around the well due to pressure pulses, the amplitude of which is changed at an adjustable rate high enough to obtain a network of diverging cracks, but avoiding brittle fracture of the coal seam with the formation of a block clogging the cracks formed.

The technical result is achieved by the fact that using the method of increasing the permeability of a coal seam through wells drilled from a mine, including creating a cavity in a coal seam by cyclically increasing and decreasing the fluid pressure in the well or borehole and exposing the formation to low-frequency high-pressure pressure pulses with increasing fluid pressure in the well, a cyclic increase and decrease in fluid pressure is created through a hydraulic multiplier mounted on the wellhead, and then a smaller area of the working surface of the hydraulic multiplier acts on the fluid filling the hole, the piston of a larger area of the working surface is affected by compressed gas, the volume of a portion of the fluid injected into the reservoir is determined by the stroke length of the hydraulic multiplier, the pressure and rate of injection of fluid into the reservoir are controlled by the pressure of the compressed gas, the ratio of the areas of the working surfaces of the pistons of the hydraulic multiplier and the feed rate of compressed gas.

This method allows you to inject liquid into the reservoir in portions of a certain volume with adjustable pressure and injection rate, which allows you to create a network of cracks taking into account the geological and physical properties of a particular section of the coal seam.

An example of a device for implementing the proposed method is shown in figure 1, in which: 1 - a hole filled with water; 2 - housing of the hydraulic multiplier; 3 - the piston; 4 - receiver; 5 - valve; 6 - valve reverse piston; 7 - funnel topping up the liquid.

The method is implemented as follows. At the mouth of the hole 1, a hydraulic multiplier housing 2 is installed and the joint is sealed. A piston 3 of a smaller area of the working surface of the hydraulic multiplier is in contact with the fluid filling the hole, a piston 3 of a larger area of the working surface of the hydraulic multiplier is connected to the receiver 4 through valve 5. The receiver 4 is filled with compressed air or inert gas. The valve 5 has a design that allows you to smoothly adjust the flow area. The receiver 4 is also connected to the housing of the hydraulic multiplier 2 on the reverse side of the piston 3 with a larger working surface area through the piston return valve 6. Valves 5 and 6 connect the cavity of the hydraulic multiplier with the receiver or with atmospheric air. The receiver 4 is connected to a compressor or mine network distribution of compressed air. As the fluid filling the hole, water is used, which may contain, for example, a foam drilling fluid for cleaning and flushing old coal wells.

Suppose that in the initial position, valves 5 and 6 connect the cavity of the hydraulic multiplier with atmospheric air, the pistons are in the left position. Pre-add fluid to the hole through the funnel 7. To create pressure in the hole using a valve 5, connect the cavity of the hydraulic multiplier 2 to the receiver 4, the compressed gas moves the piston 3 to the right position. Under the action of the piston 3, which increases the pressure of the liquid in the hole 1, cracks form in the coal seam. Then, by switching the valve 5, the supply of compressed gas to the hydraulic multiplier is stopped, using the piston return valve 6, the receiver 4 is connected to the hydraulic multiplier from the back of the piston 3 and returned to its original position. Before the next cycle of creating pressure in the hole 1 through the funnel 7, if necessary, add fluid.

For example, if the diameters of the pistons of the hydraulic multiplier are 50 mm and 200 mm, then the ratio of the areas of the working surfaces of the pistons will be 1/16, at a pressure in the mine network of compressed air distribution of 5 atm, a pressure of 80 atm will be applied to the fluid in the hole.

It is known that for the formation and development of cracks in the formation, it is necessary to apply pressure for at least half a second (Mikhalyuk A.V., Voitenko Yu.I. Impulse rock fracture. Academy of Sciences of Ukraine. Institute of Geophysics named after S.I.Subbotin. - Kiev: Naukova Dumka, 1991 .-- 204 s). The optimal duration of the pressure pulse in the hole should be considered 1-5 seconds. Under such conditions, several cracks form, diverging from the hole. A slow increase in pressure promotes the formation, as a rule, of one crack, which must be fixed with a proppant to prevent closure after depressurization. A rapid increase in pressure in the hole leads to brittle fracture of the rock with the formation of a bar which clogs the cracks and inhibits their development.

Depending on the geological conditions and the state of the formation, it is possible to control the volume of injected fluid in one cycle by limiting the length of the piston stroke 3. The pressure created in the borehole by the hydraulic multiplier and the speed of the piston are controlled by the pressure in the receiver, the ratio of the areas of the working surface of the pistons of the hydraulic multiplier and a compressed gas feed rate, which is determined by the degree of opening of valve 5.

The number of fluid supply cycles into the reservoir is determined by the methane release rate. Various processing schemes are possible. For example, initially, the injected volume of fluid is limited into the formation and a network of short cracks is created, after which, due to the supply of a large volume of fluid and high pressure, the cracks develop in length and branch. Then process more remote sections of the reservoir.

Claims (1)

A method of increasing the permeability of a coal seam through wells drilled from mine workings, including creating a cavity in the coal seam by cyclically increasing and decreasing the fluid pressure in the well or borehole and exposing the formation to low-frequency high-pressure pressure pulses with increasing fluid pressure in the well, characterized in that a cyclic increase and decrease in fluid pressure is created through a hydraulic multiplier mounted on the mouth, the piston having a smaller working area the surface of the hydraulic multiplier acts on the fluid filling the hole, the piston of a larger area of the working surface is affected by compressed gas, the volume of a portion of the fluid injected into the reservoir is determined by the stroke length of the hydraulic multiplier, the pressure and rate of injection of fluid into the reservoir are controlled by the pressure of the compressed gas, area ratios the working surfaces of the pistons of the hydraulic multiplier and the feed rate of compressed gas.