UA17815U - Method of degassing and methane extraction from gas-bearing coal-bed massif at pillar system of slant coal seams development - Google Patents

Abstract

Method for degassing and methane extraction from gas-bearing coal-bed massif at pillar system of development of slant coal seams includes penetration of technological field working in bearing rocks of the base to whole length of the extraction pillar before beginning of bed development, with drilling screening wells to the base of the bed, insulated methane discharge from degassing wells to the surface. Before beginning of working-out coal bed inbearing rocks of the base one determines the zone of stationary support pressure from the seam being developed, zone of activation of shift due to effect of extraction works at working-out coal bed, angles of complete destruction (angles of unloading) and position of the planes of unloading from theextraction pillar being worked-out and neighboring worked-out pillar, limiting shift angle, line of bend of the bearing rocks of ceiling of the neighboring worked -out extraction pillar, zones of connection of gas-bearing beds and the unloading plane of the zone of complete shift of extraction pillar being worked out, and with line of bend of bearing rocks of the ceiling of the neighboring extraction pillar.

Description

Description of the invention

The useful model refers to the mining industry. It can be used for degassing of coal 2 seams, gas-bearing rocks, produced space and methane extraction.

There is a known method of degassing of a coal-bearing layer, which includes the penetration of a drainage working in the roof of a gas-bearing layer at a distance from the layer that does not exceed seven times the width of the drainage working, installing fasteners in the working and drilling drainage wells from it to satellite gas-bearing layers and the developed gas-bearing layer

PI. 70 The disadvantage of this method is that drainage work takes place in a zone of increased rock pressure, and due to this, it has low stability and a short service life, falling into the zone of rock collapse of the immediate roof of the developed layer. Degassing wells drilled from the drainage pit are cut, compressed, and capture the methane-air mixture with a low concentration of methane due to the aerodynamic connection of the catchment pit with the ventilation flow. 12 The closest in terms of technical essence and the result that can be achieved (the closest analogue) is the method of methane canting at the extraction site, which includes carrying out catchment production in the intervening rocks of the bottom of the developed layer, drilling degassing wells from it to the developed layer, shielding wells in the bottom of the layer and isolated methane discharge to the surface |21.

The disadvantage of this method is the low stability of the catchment production and degassing wells, which are affected by rock pressure and temporary support pressure from the developed formation, as well as the connection (fusion) of the methane-air flow of the catchment production with the ventilation flow.

The basis of the useful model is the task of ensuring a long service life of technological field production, increasing the efficiency of degassing wells drilled from it, and improving the quality of the extracted methane. 29 The set task is achieved by the fact that in the method of degassing and extraction of methane from a gas-bearing coal massif with a column system for the development of shallow coal seams, which includes conducting field technological production along the entire length of the excavation column in the containing rocks of the sole before the beginning of working out the seam, drilling from it shielding wells in the bottom of the formation, isolated methane discharge from degassing wells to the surface, in accordance with a useful model, before the beginning of the development of the coal seam, determine the zone of stationary support pressure from the developed formation, the zone of activation of shifts from -/- che influence of cleaning works during the development of the coal seam, angles of complete displacements (unloading angles) and planes of unloading from the developed and adjacent spent excavation pillar, the limit angle of displacements, the line of inflection (hanging) of the host rocks of the roof of the adjacent spent excavation pillar, the zones of connections of gas-bearing formations located in the roof of the working layer, with the unloading plane of the zone of full displacements of the mining column being worked out and with the inflection line of the containing rocks of the roof of the adjacent mining column, and the field technological production is carried out in the unloaded sole of the containing rocks of the adjacent spent mining column outside the zone of influence of the stationary supporting pressure from of the developed reservoir and the influence of the zone of activation of displacements from carrying out cleaning works, two groups of degassing wells are additionally drilled from the "field technological production, and the first of them - in front of the cleaning Z 0 pit before the start of working out the excavation column in the unloading zone, which is located on the connected gas-bearing reservoirs with the line of inflection of the rocks of the roof of the spent adjacent excavation column, and the second - behind the "cleaning blowout into the unloading zone at the junction of the gas-bearing layers with the unloading plane of the zone of full displacements of the spent column, after subsidence and completion of the active phase of the ears of the immediate roof of the developed formation connect all the degassing wells to the degassing network, while the isolated removal of methane to the surface is carried out by the wells of the first group before the start of the excavation pillar, and by the wells of the second group and shielding wells - during the -I development of the excavation pillar.

Determining the zone of stationary support pressure from the developed layer (angle o) is necessary to determine the boundaries of the unloading zone in the containing rocks of the sole of the previously developed adjacent excavation column - 70 for the rational location of the field technological product in it.

Taking into account the influence of the zone of activation of shifts (I 4) containing rocks of the roof of the layer being developed, sl will allow to determine and correct the location of the technological field work (I »I o), reducing the impact of cleaning works on the stability of the work.

Determining before the start of working out of the reservoir the angles of total displacements ( зу ) of the mined column being mined and the adjacent mined column, the limit angle of displacements ( 53 ) of the mined mined column, the location of the fold line of the rocks of the roof of the adjacent mined column will make it possible to more accurately predict the location of gas reservoirs in the forged coal-bearing massifs (zones of inflection, suspensions and stratification of gas-bearing rocks, location of Weber cavities). в Conducting the field process production in the unloaded base of the host rocks along the entire length of the adjacent mining column before the start of cleaning works and outside the zone of influence of the stationary supporting pressure from the developed layer in the host rocks of the base will ensure long-term and maintenance-free support of the field process production for the entire life of the mining column and of the process of carrying out degassing works, as well as reliable sealing and stability of degassing wells during the entire time 65 of methane extraction from gas collectors.

The drilling of the first group of degassing wells from the field process, ahead of the lava outcrop before the start of the extraction column, in the unloading zone, which is located at the junction of the gas-bearing layers with the fold line of the rocks of the roof of the previously developed adjacent extraction column, will allow the selection of a portion of methane from the fake roof of the coal massif in advance , before the start of working out of the mining column and, thanks to this, to significantly reduce the high gas content of the mining area during the working out of the coal seam, as well as to ensure high stability of degassing wells.

Drilling of the second group of degassing wells behind the lava outcrop in the unloading zone at the junction of the gas-bearing formations with the unloading plane of the zone of full displacements of the working pillar, after subsidence and completion of the active phase of displacements of the immediate roof of the developed formation significantly 7/0 Reduces the probability of overpressure and shearing of gas-receiving parts of degassing wells , and, therefore, increases their service life.

Connecting all degassing wells to the degassing network of the mine will prevent mixing of methane extracted from the wells with the ventilation stream of the excavation area, which will significantly improve the quality of methane and its suitability for utilization.

The use of the proposed method will ensure a high load on the cleaning pits of multi-gas coal seams, will significantly increase labor safety and will allow the simultaneous extraction of methane suitable for utilization.

The essence of the useful model is explained by the drawing, where Fig. 1 shows, as an example, a schematic diagram of the method of degassing and methane extraction (in plan), Fig. 2 - a section along A-A in Fig. 1.

The following designations are given on the drawing: field technological production 1, developed layer 2, the boundary plane of the zone of influence of the stationary supporting pressure of the developed layer in the host rocks of the sole З, the adjacent spent mining pillar 4, the mining pillar 5 being worked out, the host rocks of the base of the adjacent spent mining pillar b, the zone of complete displacements of the adjacent spent pillar 7, the zone of complete displacements of the pillar being exploited 8, the unloading plane of the zone d of complete displacements of the adjacent spent mining pillar 9, the unloading plane of the zone of complete displacements of the pillar being exploited 10, gas-bearing formations in the roof of the developed reservoir 11 and 12, gas-bearing t layer at the base of the developed layer 13, zones of connections of gas-bearing layers 11, 12 with unloading planes of full displacement zones, respectively, 14 and 15, degassing wells of the first group 16, degassing wells of the second group 17, direct roof 18, shielding well 19, degassing network 20, yu z failure 21, ventilation stretch of the cleaning pit 22, line of inflection (hanging) 23 containing rocks of the roof of the spent excavation pillar 4, depth of laying the field work П, angle of full displacements of ushu, limit - angle of the zone of full displacements of the spent excavation pillar 4. Ge)

The method is carried out as follows.

For example, at the mine, the section of the future extraction of the coal seam is to be degassed, which is edged along

Зз5 in length by two stratum productions, and in width by ventilation and main lines. Before the start of cleaning work from the ventilation stretch 22 in the host rocks of the sole 6 of the adjacent excavated pillar 4, a field technological production 71 is carried out along the entire length of the pillar 4. The field technological product 1 is located in the host rocks of the sole 6 of the spent excavated pillar 4 along the boundary plane From the zone of influence of the stationary reference pressure from the developed layer 2, which forms an angle 459 between the normal to the developed layer 2 and the boundary plane C of the zone of the stationary reference and c pressure, counting in the direction of the developed space |Z). Taking into account the influence of the zone of activation of the displacements of the rocks containing the roof of the adjacent excavated column and the excavated column, the distance | to "» field work 1 from the ventilation stretch 22 in the direction of the excavated post there should be I » I.A, where4 is calculated according to the formula ID5):

Y a 2 9.1.K.K..K,.Ku,.ekhr (0.053 N/K), - where K - 1-1.5 - coefficient of stock of production stability; - Ki - the coefficient of influence of time on rock displacement (for Zhe 15 years K. - 1, for Zhe 15 years K- - 18.72 K/HO,228

Ip U; со Ку - the influence coefficient of the direction of removal of adjacent lava (К, - И when the lava approaches the unloading zone, Ку - - 20 03 when leaving it, К, - 0.65 during parallel mining);

Ku is the ratio of the displacements of the roof and the sole of the product (when the ratio of the displacements of the roof and the sole of the product is 60 and 4095 - K,, - 1, respectively).

With a reservoir extraction capacity of 0.8 m and production validity of 1 year, 15 N/C 65.

The depth of laying and field technological production 1 in the containing rocks of the sole b of the adjacent 29 excavation pillar 4 is taken to be equal to 2-5 m for the reasons of the effective operation of the shielding wells 19 for the extraction of methane from the developed layer 2 and gas-bearing hydrocarbon layers 13 lying in the sole of the developed layer 2 , with the strength of the host rocks of the sole of the adjacent excavation pillar 6 equal to Her » 4-5 according to Protodyakonov |5)|.

The parameters of zones of total displacements 7 and 8 (angles of total displacements, positions of their unloading planes) 60 of the spent 4 and notch 5 pillar that is being worked out are determined in accordance with the recommendations of |Z, 41. The angle of total shifts for layers with a gentle dip is 552 for the conditions of Donbass and determines the position of the unloading planes of the zones of full displacements 9 and 10. The limit angle of displacements is assumed equal to 59 - 702 |4). The coordinates of the points of inflection of the rocks of the immediate and main roof 4 (the amount of suspension of the rocks of the roof) of the spent excavation pillar 4 is determined by the formula |4|: b5 where 2 is the distance from the gas-bearing to the developed layer.

Between the angle of full displacements y and the limiting angle of displacements 53 of the adjacent spent excavation column 4 are the unloading zones and the most likely location of gas collectors capable of releasing free gas. The average position of these zones is determined by the value 4.

Zones of connections (positions of gas collectors) 14, 15 of gas-bearing formations 11 and 12 with unloading plane 10 of the zone of complete displacements (coordinates of gas collectors in the roof) of the developed formation and zone 7/0 of connections of gas-bearing formations 11 and 12 with the fold line 23 of the rocks of the adjacent roof are determined. of the used notch pillar 4.

From the field process production 1 to the development of the coal seam 2, degassing wells of the first group 16 are drilled in the unloading and connection zones 14 and 15 of the gas-bearing layers 11 and 12 and carry out the primary extraction of methane from the unloading and connection zones (roof rock bending zones) 14 and 15. Corner in this case, it is expedient to take the turn of 7/5 of degassing wells 16 equal to 452 or more. The preliminary extraction of methane from the long-term existing zones of stratification and unloading reduces the multi-gas content of the excavation area long before coal seam 2 is worked out.

The wells of the second group 17 are drilled with the use of water and gas drainage devices following the clean-up production, after the completion of the main active shifts of the immediate roof 18 of the developed layer 2.

The angle of elevation of the wells is taken to be at least 252, and the angle of reversal is 502. Shielding wells 19 are drilled, which take methane from the unloading zone in the marginal part of the developed layer 2. After the passage of the lava, the shielding wells 19 are used for degassing gas-bearing rocks and satellites 13, which lie in the host rocks of the crushed sole. In order to improve the ventilation of the excavation area and degassing of the produced space, it is provided for the connection of the field technological production 1 with the ventilation stretch of the lava 22 with the help of the failure 21. Before taking methane from the massif, all the degassing wells 16, 17 and 19 - are connected to the degassing pipeline network 20 through which the methane is discharged on the surface for disposal.

Sources of information: 1. A.S. USSR, Mo1584486, cl. E21E 7/00, DSK Me000041, 1983. 2. A.S. USSR, Mo1802165, cl. E21E 7/00, blvd. Mo10, 1993. Io) 3. Kuzmin A.S., Kalyuzhnyi N.T., Vidulin A.E. The location of field fallows during the development of coal seams. M., Nedra, 1981. - 188 p. - 4. Myakenky V.I. With the movement and degassing of rocks and coal seams during cleaning operations. K.: Naukova (oo)

Dumka", 1975. 5. Zborshchik M.P., Nazimko V.V. Protection of shafts of deep mines in unloading zones. - K.: Tehnika, 1991. - - 2A48p. h

Claims (1)

The formula of the invention " The method of degassing and extraction of methane from a gas-bearing coal massif in the pillar system of the development of shallow coal seams, which includes the implementation of technological field mining in the host rocks of the sole along the entire length of the mining pillar before the beginning of the development of the seam, drilling from it shielding "» wells into the bottom of the formation, isolated methane discharge from the degassing wells to the surface, which is distinguished by the fact that, before the beginning of the development of the coal seam, in the containing rocks of the bottom, a zone of stationary support pressure from the developed formation is determined, a zone of activation of shifts due to the influence - cleaning operations during the development of the coal seam, the angles of complete displacements (unloading angles) and the position of the unloading planes from the developed mining pillar and the adjacent spent pillar, marginal 7 angle of displacements, the line of inflection of the host rocks of the roof of the adjacent spent excavation pillar, the zone of connection of gas-bearing layers located in the roof of the reservoir being exploited, with the unloading plane of the zone of complete displacements of the excavation pillar being exploited, and with the line of inflection of the containing - the rock of the roof of the adjacent excavation column, and the field technological production is carried out in the unloaded sole from the containing rocks of the adjacent spent excavation column outside the zone of influence of the stationary supporting pressure from the developed layer and the influence of the zone of activation of displacements from carrying out cleaning works, additionally drilling from the field technological production two groups of degassing wells, and the first of them - in front of the cleaning hole before the start of the excavation pillar into the unloading zone, which is located at the junction of the gas-bearing layers with the line of inflection of the rocks of the roof of the spent adjacent excavation pillar, and the second - behind the cleaning hole into the unloading zone, which is located at the connection of gas-bearing formations with the unloading plane of the zone of full displacements of the working column, after settling and completion of the active phase of displacement of the immediate roof of the developed formation, all degassing wells are connected to the bo degassing network, while isolated from from methane to the surface by wells of the first group is carried out before the start of excavation pillar development, and by wells of the second group and shielding wells - during development of the excavation pillar. b5