RU2333363C1 - Method of monitoring gas emission during mining operations in series of highly gaseous coal seams - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to the mining industry and can be used for fighting against explosive gas during performance of mining operations in series of superimposed highly gaseous seams. The method includes mining in coal seams by long columns, formation of a gas collector from the network of drainage galleries, formation of a conduit for draining gas out of the seams into the gas collector by drilling wells from drainage galleries into virgin coal and release of gas out of the gas collector from the surface into the wells equipped with gas suction installations. During this process first of all dislocation of the fracturing zone formed in virgin coal during seam extraction in series is determined. In this case drainage galleries are mined in the offgrade seam that lies above the series of coal seams in the fracturing zone with formation of the drainage stratum before the beginning of extraction of the first seam intended for mining at first instance and which features minimal gas content. As the drainage stratum of the well is prepared boreholes for drainage of gas out of the seams are drilled from drainage galleries to the soil of the bottom formation in the series with subsequent force impact through these boreholes onto the coal seam e.g. by camouflet blasting and wells are drilled from the surface to a depth of the drainage stratum and beyond the same with subsequent connection of each well with the outer drainage gallery by providing an additional working between them. After preparation of the drainage stratum for release of gas into it and prior to beginning of excavation of seams gas is released out of pre-formed network of fractures in virgin coal, which after formation of drainage courses escapes out of them into the workings of the drainage stratum and released out of them due to drawdown developed by gas suction installations. During excavation of the first coal seam gas under the influence of stoping in the said seam escapes from the mined out space in this seam through the fractures in the fracturing zone into the workings of the drainage stratum, with subsequent removal of gas from them to the wells from the surface the drawdown state in the "drainage stratum - wells from the surface" being maintain higher than that generated in the stoping face of the seam mined. Further due to propagation of fractures during excavation of other coal seams in the series gas is still released out of workings of the drainage stratum, into which it ingresses continuously out of newly formed fractures in the coal massif in the process of excavation of each seam and from mined out spaces of these seams.

EFFECT: increased efficiency of monitoring gas emission and safety of stoping by the gas factor.

3 cl, 7 dwg

Description

The invention relates to the mining industry and can be used to combat explosive gas in pillar mining systems suites close high-gas coal seams.

There is a known method of gas evolution control during the development of a suite of highly gas-bearing coal seams prone to spontaneous combustion, including working out a excavation field with long columns along strike, excavation using a bezel-less technology with the removal of the gas-air mixture from the worked-out space into the air-driven working out through the drainage drift, conducted along the underlying layer of the developed group and connected by means of drainage ditches with ventilation drifts of the first pillars of overlying layers, blowing the fan at the mouth of the exhaust outlet, and before mining the extraction field to the initial mining, choose a formation whose coal is less prone to spontaneous combustion and which is worked out in a descending order, and the subsequent mining of worked-up and worked-out layers is carried out in an ascending order with the discharge of the gas-air mixture to the drain drift through inter-layers and the developed space of the initially worked out formation (1).

A disadvantage of the known method for controlling gas evolution is its low efficiency, since gas is discharged in the downward direction through interstratal cracks, the filtering paths of which are represented by a finely cracked structure with high aerodynamic drag. As a result, a significant amount of gas may accumulate in the worked out spaces of the underworked layers, despite the creation of a fan depression in the well. In addition, the magnitude of the depression may not be quite sufficient, then the gas will not be able to move in the downward direction, and due to its physical properties (gas moves only upwards), it will accumulate in the worked out spaces of the underburden.

Moreover, according to the known method, it is possible to test the formation suite only in the downward direction, since during the mining of the layers in the upstream direction, the gas face of the upper face of the coal seam to be mined may be gas due to the incomplete exit of gas from the worked out space of the worked seam.

Thus, the known method has a number of significant drawbacks that reduce the efficiency of its use, since it does not allow gas safety in the excavated sections of the worked out seams in the formation and, accordingly, the safety of treatment operations during the development of high-gas coal seams.

The closest to the claimed method according to the achieved result and physical nature is a method for controlling gas evolution during mining of a coal seam suite, including dredging seams in a descending order by long columns along strike along an aimless technology with the removal of a part of the gas released into the outgoing stream of the dredging section, while working out the overlying the reservoir create a gas collection tank, which can be used as the developed space of the reservoir or a network of drainage workings, and there are ways of gas drainage from the underlying reservoir to the gas collecting tank, and when mining the underlying reservoir, the working face is located under the gas collecting tank, create a pressure drop in it towards the gas collecting tank and gas is removed from it. The ways of gas drainage from the underlying reservoir to the gas reservoir are formed by drilling wells in the inter-reservoir and creating oriented hydraulic fractures in it, which exit into the gas reservoir on the overlying reservoir and into the collapse zone of the roof of the underlying reservoir (2).

In the known method, as compared with the technical solution (1), a slight decrease in gas evolution in the working faces of the produced formations is achieved due to the formation of microcracks of hydraulic explosion in the interdomain, which ensure the flow of gas from the underlying formation into the gas collection tank with subsequent removal of gas-suction units from it.

However, in view of the need to ensure the safety of cleaning operations by the gas factor, the degree of gas release in the working faces of the reservoir remains quite high due to the fact that:

- the adopted scheme for mining coal seams in the formation in the downward direction reduces the degassing efficiency of the underlying underlying seams, especially when mining more than two layers in the suite, since hydraulic fractures in inter-layers do not represent an extensive network of cracks, which does not contribute to the active flow of gas from the worked out spaces of these layers in the gas reservoir of the overlying reservoir;

- the use of the worked-out space of the overlying formation as a gas collection tank is ineffective, because the worked out space is a system of cracks with high aerodynamic drag, which, in turn, reduces the throughput of such a gas collection tank;

- in spite of the use of a system of vertical wells through which gas is sucked from the gas collecting tank, this does not reduce the gas hazard of the treatment faces of the excavated sections of the worked out formations, because gas is removed from only one source of its release with subsequent entry into the gas collecting tank, namely from the worked out space during mining of the underlying formation;

- in connection with the foregoing, the issue of the possibility of gas removal from such a source of its emission as from an untouched coal-bearing mass prior to the start of mining coal seams in order to reduce gas release into the treatment faces of the worked seams has not been resolved. This limits the technological capabilities of the known method.

The disadvantages of this method should also include the fact that the implementation of the gas collection tank from the drainage openings, which are the preparatory openings, contouring the excavation areas, from a technical and technological point of view is impossible, because these workings should be supported in the worked out space of the overlying overburden.

In addition, a significant number of wells drilled from the surface will be required to divert gas from the gas gathering vessel to the surface, which increases the cost of gas management operations during the development of the formation suite.

Despite the fact that in the known method separation between cleaning and degassing works is possible, however, this cannot significantly increase the safety of treatment works, since these works are performed at a fairly close distance from each other.

The objective of the invention is to expand the technological capabilities of the method of gas evolution and increase the efficiency of its use by reducing gas evolution into the working (treatment) space of the excavation section of each of the coal seams being mined in the formation by imparting collector properties to the untouched coal-bearing mass before the seam mining starts while ensuring complete extraction gas from the depleted spaces of these layers.

The technical result, the achievement of which provides a solution to the problem, is expressed in increasing the safety of treatment operations by reducing gas release into the working faces of the coal seams and separate treatment and degassing operations, as well as in increasing the load on the working face by reducing the influence of the gas factor on the possibility of increasing coal production from the working faces of the mined seams.

To achieve the task with the claimed technical result in a method of controlling gas evolution during the development of a suite of high-gas-bearing coal seams, including mining of coal seams with long pillars, creating a gas collection tank from a network of drainage openings, forming a drainage path for gas from the layers into the gas collection tank by drilling wells from drainage openings to untouched coal-bearing mass and gas removal from the gas-gathering tank during the extraction of formations to wells drilled from the surface and equipped with a gas outlet according to the claimed technical solution, the location of the crack formation zone, which is formed in the untouched coal-bearing massif upon excavation of the seams in the formation, is preliminarily determined, and the drainage workings of the gas-collecting reservoir are carried out on the substandard formation (or interlayer) lying above the formation of coal seams to be excavated in the zone of crack formation, with the possibility of forming a drainage horizon before the beginning of the seam mining, planned to the first in the formation and having the least gas accumulation, while preparing the mentioned drainage horizon, the projection of each of its drainage workings on the plane of the seams is oriented between the preparatory workings that outline each excavation column of the coal seams being mined, and for the formation of an extensive network of cracks in the untouched coal-bearing massif of the well, ways of gas drainage from the strata, drilled from drainage workings to the soil of the lower coal seam in the formation with subsequent power acting through them on an untouched coal-bearing massif, for example, camouflage blasting, and wells from the surface that discharge gas from the gas-collecting tank, which is the drainage horizon, are drilled to the depth of the drainage horizon and outside it outside the working zone, with each of them connecting to extreme drainage by conducting additional work between them, then after the formation of the drainage horizon and the subsequent connection of its workings with wells drilled from the surface, until At the beginning of the coal seam extraction, gas is extracted from the pre-formed network of cracks in the untouched coal-bearing massif, which, after the formation of drainage paths, flows from them into the drainage horizons and is removed from the latter due to the depression developed by the gas suction plants, then when the coal seam is scheduled to be mined by the first , the gas along the cracks in the zone of crack formation, formed under the influence of treatment in the specified layer, leaves the worked out space of this layer the development of the drainage horizon with its subsequent withdrawal from them to the wells from the surface while maintaining the depression in the "drainage horizon - wells from the surface" system is higher than the depression created in the working face of the reservoir, further due to the development of cracks in the crack formation zone during excavation of the second and of each subsequent coal seam formation continues to divert gas from the workings of the drainage horizon, into which it constantly comes from newly formed cracks in the coal-bearing massif during the extraction of each coal seam and from the developed spaces of these seams.

Moreover, after the extraction of the coal seam, scheduled for mining first, the remaining coal seams in the formation work out in any order.

In addition, in order to economize the process of gas removal from the workings of the drainage horizon from the surface, large diameter wells are drilled at least in the range of 1.0-3.0 m.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources, made it possible to establish that the applicant has not found an analogue characterized by features identical to all the essential features of the claimed invention set forth in the claims.

Therefore, the claimed technical solution meets the condition of patentability of the invention - "novelty."

The causal relationship between the set of essential features of the claimed technical solution and the achieved technical result is as follows.

The sign - “pre-determine the location of the zone of crack formation, which is formed in the untouched coal-bearing massif during excavation of formations in the formation” - is necessary to select in advance the location of the gas-collecting tank in the thickness of the untouched massif, namely, in the zone of cracking, which appears in it as the coal seams are mined and along the cracks of which gas is drained from the depleted spaces of these layers.

At the same time, in the prototype (2), this zone is not used to remove gas from the worked out space of the underlying formation, since only wells drilled in inter-layers serve for these purposes. However, this is not enough to most fully extract gas from the developed space of this formation.

The sign - "and the drainage workings of the gas-collecting tank are carried out on an off-grade formation (or interlayers), lying above the formation of coal seams to be excavated in the crack formation zone, with the possibility of forming a drainage horizon before the formation is excavated, scheduled to be worked out first in the formation and having the least gas mobility" - is fundamental in the claimed method, providing a new approach to creating a gas collection tank, namely in the form of a drainage horizon, which will increase the coverage area by degassing of the worked out spaces of the mined seams, but also by the degassing of the untouched coal-bearing mass both before the beginning of the coal seam mining in the formation and during their excavation, and, accordingly, to increase the flow of the emitting gas into the gas-collecting tank - the drainage horizon, i.e. the usefulness of this feature is obvious. Moreover, the creation of a gas collection tank in the form of a drainage horizon will increase its throughput compared to the prototype (2), in which it is limited by the amount of worked space of the overlying formation. In addition, the development of drainage horizons in the substandard reservoir is more economical than conducting them in waste rocks.

Moreover, the accepted procedure for working out formations in the formation, i.e. it begins with the least gas-rich formation, provides a more secure extraction of this formation, while at the same time creating the most favorable conditions for the drainage of gas from the other more gas-rich layers when they are developed in the direction of the gas-collecting tank.

However, the applicant, conducting an additional search for known solutions in this field in order to identify features that match the distinctive features of the prototype of the features of the claimed technical solution, found that the above-described distinguishing feature is known from the prior art (3). According to this source, when degassing adjacent coal seams, a gas collection is used as a gas collection tank, which is carried out along an undermined adjacent formation before the excavation of a developed formation is started with the possibility of erecting a concrete bridge through which the pipeline passes through it. This option of degassing is applicable when the inter-layer rocks have a large strength, which causes difficulties in drilling degassing wells. It follows that the disadvantage of this technical solution is the possibility of a sufficiently small amount of gas entering such a gas-collecting vessel compared to the volume of gas remaining in the worked out space of the developed formation when performing this method of degassing. This circumstance leads to an increase in the gas content in the working face of the developed formation and, accordingly, to a decrease in the safety of treatment operations.

Despite the fact that there is a separation of treatment and degassing operations using this method, its implementation is associated with the difficulty of organizing work to link them together, and therefore it is applicable only to a separate excavation section of a developed formation and is not applicable to the development of a suite of adjacent formations into parts of a mine field.

In the inventive method, the distinguishing feature under consideration is a gas collection tank in the form of a drainage horizon capable of receiving a sufficiently large volume of gas released not only from the worked out space of the worked seams, but during degassing of the untouched coal-bearing massif with its subsequent flow to the wells from the surface, i.e. immediately outside the area (where the strata are located) of the mine field. This allows you to reduce gas evolution in the working faces of the reservoir.

Therefore, the considered distinguishing feature according to the well-known (3) and claimed technical solutions does not confirm its identity, respectively, and the popularity of the influence of this distinctive feature on the achievement of the technical result indicated by the applicant is not confirmed - increasing the safety of treatment work and increasing the load on the working face by reducing the restraining influence on the work of the gas factor.

The sign - "in this case, when preparing the drainage horizon, the projection of each of its drainage workings onto the plane of the seams is oriented between the planned workings to be carried out that outline the extraction column of the coal seams being mined" - together with the aforementioned sign is fundamental in the claimed method and characterizes the most optimal variant of the ratio adopted systems for preparing a drainage horizon for a system for preparing for excavation of coal seams in a suite, predetermining t Kim way the possibility to use for generating the drain horizon force action on the intact carboniferous array to increase its gas recovery over the prior art (2), which is carried out along the cracks gazoodacha fracturing mezhduplastyah without a branched chain.

The sign - “and for the formation of a branched network of cracks in the untouched coal-bearing massif, wells that form gas drainage paths from the seams are drilled from the drainage workings to the soil of the lower coal seam in the formation with subsequent force impact through them on the untouched coal-massif, for example, camouflage blasting” - is one of the conditions for the implementation of the proposed method and allows you to realize the possibility of forming a gas drainage path in the thickness of the untouched coal-bearing massif in order to give it (after impact on it) reservoir properties that contribute to the removal of gas flows from it, thus creating prerequisites for reducing the gas mobility of the working faces of the produced formations.

The sign - “and the wells from the surface that divert gas from the gas gathering tank, which is the drainage horizon, are drilled to the depth of the drainage horizon and outside it outside their working area, followed by each of them connecting with the extreme drainage production by conducting additional production between them” - indicates the most optimal option for the location of wells from the surface relative to the workings of the drainage horizon, which can significantly reduce the number of these wells to two compared prototype (2), i.e. this feature is necessary for carrying out the invention.

The sign - “then, after the formation of the drainage horizon and the subsequent connection of its workings with the wells drilled from the surface, before the extraction of the coal seams, gas is extracted from the pre-formed network of cracks in the untouched coal-bearing mass, which, after the formation of drainage paths, flows from them into the workings of the drainage horizon and is removed from the latter due to depression developed by gas suction plants ”- characterizes the novelty of the degassing process of an untouched coal-bearing massif by imparting collector properties to it in advance, which allows, prior to the development of coal seams, to extract gas from the untouched coal-bearing mass and, accordingly, to reduce it subsequently entering the treatment faces of the worked seams.

The sign - “further, during the extraction of the coal seam, scheduled to be mined first, the gas flows through the cracks in the crack formation zone formed under the influence of treatment operations in the specified seam, leaves the worked out space of this seam in the development of a drainage horizon with its subsequent removal from them to the wells from the surface at maintenance of depression in the system “drainage horizon - surface wells” is higher than the depression created in the working face of the produced formation ”- together with the above sign contributes to the most complete removal of gas from the worked-out space of the produced formation due to gas-conducting channels in the crack formation zone and existing cracks in the untouched coal-bearing massif. These circumstances lead to a decrease in gas release into the working space (face) of the produced seam, which contributes to an increase in the safety of treatment operations and, as a result, an increase in the load on the face due to a decrease in the influence of the gas factor on coal mining.

The sign - “in the future, due to the development of cracks in the crack formation zone during the excavation of the second and each subsequent coal seam, the formations continue to divert gas from the workings of the drainage horizon, into which it constantly comes from newly formed cracks in the coal-bearing massif during the excavation of each coal seam and from the worked out spaces of these layers ”- enhances the technical effects described above due to the ongoing process of developing a system of cracks in an untouched coal-bearing massif under the influence of treatment operations reservoirs along which gas from the last and depleted spaces of these beds moves towards the drainage horizon under the influence of its depression. That is, this feature confirms the increased efficiency of the inventive gas emission control technology in comparison with the prototype (2), in which the crack formation zone does not participate in the degassing of the worked out spaces of the worked out formations.

In addition, from the characteristics of this feature it follows that the treatment and degassing works are separated in space, which, on the one hand, improves the safety of treatment works, and on the other hand, reduces the overall economic costs of implementing the inventive method by eliminating the use of degassing pipelines .

The sign (paragraph 2 of the formula) - "after the extraction of the coal seam, scheduled to be mined first, the remaining coal seams in the suite are worked out in any sequence" - indicates the possibility of implementing the method for any order of mining the coal seams, since regardless of the accepted order, the completeness of gas extraction is achieved from the worked out space of the working seams due to the formed paths of gas drainage in the coal mass and the formation of a developed system of cracks, while ensuring a reduction in gas evolution and in the face of each of the worked out formations in the formation, i.e. the technical result set by the applicant is achieved.

The sign (paragraph 3 of the formula) - “in order to economize the process of gas removal from the workings of the drainage horizon from the surface, two large-diameter wells are drilled, at least within 1.0-3.0 m” - reduces the economic costs of gas removal from the workings drainage horizon, and more specifically reduces the energy consumption of gas suction installations due to the reduction of aerodynamic resistance to gas movement through large diameter wells, therefore, it is enough to drill only two such wells.

Thus, the set of essential features characterizing the essence of the proposed method allows to increase the efficiency of gas evolution control by reducing the gas release into the working (treatment) space of the excavation section of each coal seam being mined, which makes it possible to improve the safety of coal treatment and coal mining reducing the influence of the inhibitor of gas evolution.

It follows from the foregoing that the essential features of the claimed invention are in a causal relationship with the achieved technical result and from the analysis of the prior art in this field are not explicitly obvious to a specialist, which characterizes the "inventive step" of the claimed technical solution.

The information set forth in the application materials is sufficient for the practical implementation of the invention.

The essence of the proposed method is illustrated in graphic materials, where:

figure 1 shows a schematic diagram of the location of the drainage horizon relative to the retinue of highly gas-bearing coal seams (before they are removed) and wells from the surface, in isometry (rocks of the coal-bearing massif are not conventionally shown);

figure 2 is a view along A in figure 1, the position of the mining operations in plan for the lower layer, accepted for mining first;

figure 3 is a section along BB in figure 1, a diagram of the drilling of wells from the workings of the drainage horizon through the untouched coal-bearing massif to the soil of the lower coal seam in the suite;

figure 4 is the same as in figure 3, a diagram of the formation of a branched network of cracks in an untouched coal-bearing array;

figure 5 is a diagram of the control of gas evolution during the period of extraction of the reservoir, scheduled for development by the first and having the least gas mobility;

Fig.6 is a fragment of Fig.5 (enlarged view), a section of the coal-bearing mass at the time of the formation of the collapse arch and the crack formation zone during coal excavation in the excavation section of the initially mined seam in the formation;

Fig.7 is a diagram of the control of gas evolution during the period of excavation of the formation in the retinue, part-time work of the initially worked-out formation, a vertical section.

The proposed method for controlling gas evolution during the development of a suite of high-gas-bearing coal seams is considered as an example of mining a suite of two seams 1 and 2, the extraction of coal of which is carried out by long columns along strike along the bezelikovoy technology.

Before mining a section of the mine field, the degree of gas abundance of seams 1, 2 is estimated and the formation having the lowest gas abundance, for example seam 1, is selected for initial development. After this, based on the specific geological conditions of occurrence of coal seams 1 and 2, a crack formation zone 3 is determined. which is formed in the future during the extraction of these layers. To determine the location of the crack formation zone 3, it is recommended to use an analytical method based on determining the amount of deformation of the rocks during their underworking, depending on the thickness of the removed coal seam and the physical and mechanical properties of the rocks.

The method is as follows.

First, create a gas collection tank from a network of drainage openings (figure 1).

For this, according to the mining plan of the mine field section to be mined, from the slopes or bremsbergs of the mine, using a well-known technology, an substandard formation 4 is opened, which lies above the formation of the layers 1, 2 to be excavated and which should be located in the future location of the crack formation zone 3. After that, before the start of the excavation of the formation 1, scheduled for development by the first as the least gas-rich, a network of drainage excavations 5 is carried out, the training system of which corresponds to the preparation system for the development of reservoirs 1 and 2, i.e. long poles along the strike on the aimless technology. From the passed network of drainage openings 5, a drainage horizon 6 is formed. At the same time, when the formation of drainage horizon 6 is formed, the projection of each of its development 5 onto the plane of seams 1 and 2 is oriented between the preparatory workings 7 planned to be carried out, outlining each excavation column 8 of the worked coal seams 1 and 2 ( figure 2).

Simultaneously with the creation of drainage horizon 6 (or after that) two wells 9 of large diameter are drilled from the surface, within 1.0-3.0 m, to the depth of the drainage workings 5 with each of them being oriented along the length of these workings 5 and beyond outside the zone of underworking by layers 1 and 2. Then each well 9 is connected to the extreme drainage mine 5 by conducting additional mine 10 between them, seal its mouth and connect to the gas suction unit 11, which creates a depression in the mine workings 5 of the drainage mountains 6 hood (1, 2).

As the drainage horizon 6 is prepared to be diverted to gas 5 to be emitted from formations 1 and 2, gas drainage paths are formed in the untouched coal-bearing massif 12 by drilling 13 from drainage openings 5 to the soil of the lower layer 1 (Fig. 3). Then, through wells 13, a force is applied to the untouched coal-bearing massif 12 by any known method, for example, camouflage blasting, in order to create an extensive network of cracks in it 14. Moreover, wells 13 can be drilled either immediately through the entire thickness of coal-bearing massif 12 within all excavation columns 8 strata 1 and 2, or within part of these extraction columns 8, if by the time of drilling wells 12 will be prepared for mining excavation field of formation 1.

After the formation of the drainage horizon 6 and the subsequent connection of its workings with wells 9 drilled from the surface, the thickness of the coal-bearing array 12, which is given collector properties due to the force acting on it before the excavation of the coal seam 1, is degassed by gas extraction from a pre-formed network of cracks in the array 12, which, through the formed drainage paths in the form of a branched network of cracks 14, comes from them to the workings 5 of the drainage horizon 6 and is diverted from the latter to the wells 9 with p the surface due to the depression developed by the gas suction plants 11. Due to the preliminary degassing of the coal-bearing array 12, a further decrease in gas evolution in the working face is ensured when the formation 1 is excavated and, accordingly, later when the formation 2 is excavated (Fig. 4).

Further, during the excavation of the formation 1, which is accepted for initial mining, in addition to the collapse zone 15, a crack formation zone 3 is formed, along the cracks 16 of which, as well as along the cracks 14 in the coal-bearing massif 12, gas from the worked out space of the formation 1 enters the workings 5 of the drainage horizon 6 and is discharged of these, to wells 9 from the surface due to the maintenance of depression in the system “drainage horizon - wells from the surface” is higher than the depression created in the working face of the producing formation (FIGS. 5, 6).

Later, when the formation 2 is excavated, cracks 16 develop in the crack formation zone 3, while gas from the newly formed cracks 16 in the coal-bearing mass 12 and from the worked-out space of this formation constantly flows into the workings 5 of the drainage horizon, from which are discharged according to the above-described scheme (Fig. 7).

If there are more than two coal seams in the suite, after mining the least gas-rich seam, the remaining seams are worked out in any sequence when performing in each of them similar work to mining seam 1.

The proposed scheme for the degassing of high-gas-bearing coal seams worked out in the suite provides the most complete extraction of gas from the worked out spaces of these seams and, as a result, a decrease in its release into the working treatment faces of the worked seams.

If necessary, all the described operations by the claimed method can be similarly carried out in other areas of the mine field.

Thus, as a result of performing the new operations presented in the claimed method, it became possible to expand the technological capabilities of the gas evolution control method and increase its efficiency by reducing gas emission into the treatment faces of the reservoirs, due to the collection of intact coaliferous massif before the development of reservoirs in the formation at ensuring the completeness of gas extraction from the worked out spaces of the worked-out formations. Due to this, safe working conditions for coal mining on high-gas-bearing coal seams are ensured while simultaneously increasing coal production from them due to a decrease in the limiting effect of the gas factor.

Sources of information taken into account when drawing up the description of the invention:

1. USSR author's certificate No. 1476151, cl. E21F 7/00, 1986

2. RF patent No. 2118458, E21F 7/00, 1997 (prototype).

3. Interim guidance for the degassing of coal mines. - M .: Nedra, 1967, p. 56-61.

Claims (3)

1. A method for controlling gas evolution during the development of a suite of high-gas-bearing coal seams, including excavation of coal seams with long pillars, creating a gas collection tank from the drainage network, forming a drainage path for gas from the formation into the gas collection tank by drilling wells from the drainage excavations into an untouched coal-bearing array, and discharging gas from the gas collecting tanks when excavating formations to wells drilled from the surface and equipped with gas suction units that provide gas flow along its drainage paths, characterized in that the location of the crack formation zone, which is formed in the untouched coal-bearing massif upon excavation of the seams in the formation, is preliminarily determined, and the drainage workings of the gas-collecting reservoir are carried out along the substandard formation or interlayer lying above the formation of coal seams to be excavated in the formation zone, with the possibility of forming a drainage horizon prior to the start of the excavation of the formation, scheduled to be worked out first in the suite and having the lowest gas mobility, while preparing the mentioned wood of the important horizon, the projection of each of its drainage workings onto the seam plane is oriented between the preparatory workings planned to be carried out, outlining each excavation column of the coal seams being mined, and for the formation of an extensive network of cracks in the untouched coal-bearing massif of the well, the formation paths of gas drainage from the seams are drilled from the drainage workings to the bottom soil a coal seam in a suite with subsequent force action through them on an untouched coal-bearing massif, for example, camouflage by digging, and wells from the surface that divert gas from the gas gathering tank, which is the drainage horizon, are drilled to the depth of the drainage horizon and beyond outside their working area, followed by each of them connecting with the extreme drainage output by conducting additional production between them, then after the formation of the drainage horizon and the subsequent connection of its workings with the wells drilled from the surface, gas is extracted from the preliminary a broken net of cracks in an untouched coal-bearing massif, which, after forming drainage paths, flows from them into the drainage horizons and is removed from the latter due to depression developed by gas-suction plants, then, when a coal seam is first to be mined, gas is cut through cracks in the cracking zone formed under the influence of treatment in the specified layer, leaves the worked out space of this layer in the development of the drainage horizon with its subsequent removal from them to the wells from the surface while maintaining the depression in the system “drainage horizon - wells from the surface” is higher than the depression created in the working face of the produced seam, in the future, due to the development of cracks in the crack formation zone during excavation of the second and each subsequent coal seam formation, gas continues to be drained from the workings of the drainage horizon into which it constantly comes from newly formed cracks in the coal-bearing massif during the extraction of each coal seam and from the worked out spaces of these seams. 2. The method according to claim 1, characterized in that after the extraction of the coal seam, scheduled for mining first, the remaining coal seams in the suite work out in any sequence. 3. The method according to claim 1, characterized in that in order to economize the process of gas removal from the workings of the drainage horizon from the surface, large diameter wells are drilled at least in the range of 1.0-3.0 m.

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