SU1712629A1 - Method for degassing gassy coal seams - Google Patents

Abstract

The invention relates to mining. The goal is to increase the efficiency of gas extraction from the reservoir hydroprocessing zones. The well is drilled from the day surface to a coal seam and hydrotreated. Simultaneously with hydroprocessing in the soil of the reservoir, field excavations pass through one excavation column prior to commencing the preparatory work on the reservoir. After hydrotreating from field development, a series of underground wells perpendicular to the axis of production are drilled into the hydrotreatment zone. The drilling interval is determined from a mathematical expression. All degassing wells are connected to the gas suction systems and produce gas suction. The positive effect is due to the high stability of the filtering part of the degassing wells, their shorter length, with the exception of the passage of paired workings along. Blowout protection measures. 2 il.sl

Description

The invention relates to the mining industry, primarily to the coal industry, and can be used for the degassing of high gas-bearing outburst formations with a low natural permeability.

There is a method for degassing a coal seam, which includes drilling a well from the day surface to a coal seam, injecting working fluid into it at a rate exceeding the natural injectivity of the formation, holding the working fluid in the reservoir for three to six months, pumping it out and sucking gas from the reservoir.

This method is characterized by the disadvantage that it is difficult to extract gas from the part of the reservoir lying below the opening, due to the low permeability of the reservoir.

Closest to the present invention is a method of degassing a coal seam, including drilling a well from the surface to the coal seam, pumping a working fluid at a rate exceeding the natural injectivity of the formation, drilling after pumping a working fluid from a series of underground wells from a mine working to a hydrotreating zone, connecting all wells with gas suction systems and gas suction from all wells.

However, the known method is characterized by insufficient gas recovery efficiency due to the lack of consideration of the properties of the array as block-fractured, formed as a result of hydrotreatment of the reservoir, and the choice of the distance between underground wells without specifying the required decrease in gas content of the array during a certain degassing time.

and also, without clarifying the nature of gas filtration from the blocks into the cracks and into the wells over time, which makes it difficult to reliably determine the parameters of drilling of underground wells and reduces the efficiency of gas extraction from the treated zone of the formation.

In addition, the prototype does not allow carrying out reservoir preparatory development along an already degassed massif and does not provide a sufficient time for degassing prior to the start of treatment works.

The purpose of the invention is to increase the efficiency of gas extraction from the zones of hydrotreatment of the reservoir due to the targeted drilling of underground degassing wells.

The purpose of the invention is achieved by simultaneously with hydroprocessing in the soil of the reservoir through a single extraction column, before starting the preparatory work on the reservoir, field workings are made, from which a series of wells SQUAZ is drilled perpendicular to the production axis, and the interval of wells is determined from the expression

i + f

(one)

h 10

d H-5h -21,552

)

lg g- (

4,962

P2

(1 - 0.32 t) -0.014

t

f 1.04 (Vo, 81gC-1 - 0.398, 968);

2 Ki „m2 g -777-; With TT "1

t

tx

h is the interval of drilling of underground wells, m;

KI - the permeability of the crack system,

"1 is the function of gas flow from the blocks to the cracks;

mi is fracture porosity;

t2 - block porosity is fictitious;

t is the degassing time, s;

tx - characteristic time, s;

 normalized time;

/ and - gas viscosity. Pa s;

Ra — atmospheric pressure, Pa;

RO is the initial gas pressure. Pa;

P2 is the pressure to which it is necessary to reduce the initial gas pressure during degassing t. Pa.

Fig, 1 presents the scheme of horizontal preparation of the mine floor; in fig. 2 is a diagram of panel preparation of a mine floor.

5 The method is carried out as follows.

Wells 1 are drilled from the surface of the day, and the working fluid is pumped into the formation at a rate exceeding the natural injectivity of the formation in a volume of 1-5% of the volume of fluid required to process the entire formation zone. The wells 1 are then connected to a gas suction system (not shown).

15 Simultaneously with the harvest in the soil of the reservoir, prior to the start of the preparatory work on the section of the mine floor, one excavation column 2 carried out field operations 3 located in the soil of the reservoir and. a few meters from the local reservoir production 4, of which the degassing wells 5 are drilled into the hydroprocessing zone, mainly in the area of the reservoir sites 4.

5 The interval of drilling of wells in the hydrotreatment zone of the formation is determined from the expression (1).

Underground wells 5 are connected to a gas suction system. From the surface

0 and underground wells 5 gas is sucked together.

It is known that, as a result of hydroprocessing, the formation is broken up into a block system by trunk fractures. Gas filtration

5 in such an array comes from blocks into cracks and along cracks in wells. The nature of gas filtration in block cracking. The volume of the array must be considered to reliably determine the parameters of the wellbore.

The gas inflow to the well depends on a number of properties of the array: the permeability of the fracture system, the gas recovery rate of the blocks, the porosity of the fractures and blocks, the initial gas pressure in the blocks.

All these and other parameters were taken into account when solving the problem of gas inflow to the well in a block-fractured array. As a result, the differential

0 equations describing this process, using the finite difference method, expression (1) was obtained.

The resulting expression takes into account all the basic properties of the array. This gives grounds to speak about taking these parameters into account for a reliable determination of the drilling interval and time of degassing, is based mainly on considerations of a geometric nature and makes it impossible to determine the magnitude of decrease in gas content depending on the time of degassing, which makes planning mining operations difficult.

An analysis of field schemes for the preparation of mine fields in the Karaganda basin shows that the main field drifts were carried out to the flank ventilation shaft well (4-6 years) before the start of cleaning and preparatory work on the sections of the mine floor (wing) near which they were held. This allows the excavation of special field workings with reference to the existing ones. In this case, the data output (bremsberg or slope with the horizon and drift by the panel method of preparing the mine floor) will also exist for a long time (3-5 years).

At the same time, the wells drilled from these workings to the hydrotreatment zone will allow the array to be degassed for 3-5 years, which will increase the efficiency of reservoir degassing.

Example. In order to clarify the extent of discrepancy in determining the intervals of wells drilled by the proposed method and by the prototype method, calculations were carried out in relation to the conditions of the mine. V. I. Lenin p / p Karagandaugol.

A number of wells have been drilled from the second db field drift into the formation, sealed in such a way that the gas pressure can be measured.

The filtration characteristics of an array in the region are obtained from the curves of pressure recovery shown in the figure.

hydrodislocation.

These data will be used for calculations .;

An example of the calculation according to the method of the prototype.

The azimuth of the propagation of cracks of the greatest hydroconductivity hail; azimuth strike of mine workings Y5 175 degrees. The values of the smallest and largest hydroconductivity of the reservoir, respectively (a 52.5 m and b 75 m) Kmin, 0.11 mD, 0.16 mD. The drilling interval is determined by the formula specified in the prototype. The calculation gives a value of h 43.4 m.

An example of the calculation for the proposed method., G: -; Baseline data obtained from the experiment: PO 3-10 Pa; Ki 1.5-10 ®, 0-102 °; mi 0.01; m2 1.0; , 7x

 1p5

H-5

.with; Pa 10 Pa.

Let the pressure in the blocks be reduced to 2.7 10 Pa (i.e. by 10%) during degassing time t 500 days.

We carry out calculations according to the formula (1), having previously calculated the coefficients:

g 100; With LLP; tx 0,57.10 from 660 days; t 0.75; f -0.384; “-0,141; n 0.428; h 16.4 m

As we see, the discrepancy in the values of the intervals of drilling of wells, found in two ways, is significant: 2.6 times. The prototype does not specify how much time and how much gas content of the massif will be reduced if the wells are drilled with an interval of 43.4 m.

Thus, the proposed degassing method allows one to sufficiently accurately determine the parameters of the initiation of degassing wells drilled in the hydrotreatment zone of the reservoir, as well as the degassing time during which it is necessary to achieve a given degassing efficiency coefficient; to ensure a long (3-5 years) period of degassing of the reservoir due to the drilling of underground wells from the field workings carried out in advance; to partially or completely exclude the carrying out of the blowout preventive measures during the penetration and the carrying out of the purification works, to refuse from carrying out the barrier and preliminary degassing of the reservoir wells, as well as the pair development during the penetration; use field degassing mines to transport the mineral and supply fresh air to the lava (or sunflower), degass from the mines of the excavated areas; to provide the maximum possible degassing efficiency factor under these conditions, which will allow increasing the load on the cleaning face in terms of the gas factor and the rate of excavation of the reservoir.

Formula 3 and batching Method of degassing a high-gas-bearing coal seam, including drilling a well from the day surface to the coal seam, pumping a working fluid into it at a rate exceeding the natural injectivity of the reservoir, drilling a series of underground wells into the hydrotreating zone, connecting all wells with gas suction systems and gas suction from underground wells, characterized in that, in order to increase the efficiency of gas extraction, a series of underground wells drill from field workings that pass through the formation in the soil simultaneously

with hydroprocessing through one excavation pillar prior to the commencement of the preparatory work at the mine floor site, the underground wells are drilled perpendicular to the production axis, and the drilling interval is determined from the expression d +5 to -21.55 where p 9-9- (T962 -) ln (1-0,32t) f 1.04 (Vo.8lgC-1 - 0.398, 968); 2 Ki. p.m2. , "1 mi t .. mi;

h is the interval of drilling of underground wells, m;

Ki is the permeability of the crack system,

5ai - function of gas flow from the blocks to

cracks;

Phi1 mi - fracture porosity; t2 - block porosity is fictitious; t is the degassing time, s; tx - characteristic time, s; normalized time; ; - gas viscosity, c-Pa; Ra - atmospheric pressure. Pa; RO is the initial gas pressure. Pa; RG is the pressure up to which it is necessary to set the initial gas pressure during the degassing time. Pa.

B-b

Claims (1)

Claim A method of degassing a high-gas-bearing coal seam, including drilling a well from a day surface onto a coal seam, injecting working fluid into it at a rate exceeding the natural injectivity of the seam, drilling a series of underground wells into a hydrotreatment zone, connecting all wells to gas suction systems, and sucking gas from underground wells, characterized in that, in order to increase the efficiency of gas extraction, a series of underground wells are drilled from field workings that pass in the soil of the formation simultaneously with hydraulic treatment otkoy through one excavation column before the start of preparatory work on the mine field, while underground wells are drilled perpendicular to the axis of development, and the interval of drilling is determined from the expression h »10 ^{1 + n / 2} , In [fe (1 -0.32 t) 1-0.014 ^d t * f = 1, O4 (Vo, 8lgC-1 - 0.398 Ig -0.968): t *> h - interval for drilling underground wells, m; Κι is the permeability of the system of cracks, m, si is the function of the gas flow from the blocks to the cracks; mi is the porosity of cracks; m2 - fictitious porosity of blocks: t - time of degassing, s; tx is the characteristic time, s; t * is the normalized time; μ is the viscosity of the gas, s · Pa; Ra - atmospheric pressure, Pa; Po is the initial gas pressure, Pa; Rg is the pressure to which it is necessary to reduce the initial gas during the degassing time t, Pa. ai pa on Figure 1