SU1011858A1 - Method of working bed deposits of solid minerals - Google Patents

Abstract

1. CONSERVATION DEVELOPMENT OF PLASTIC DEPOSITS OF SOLID MINERAL RESOURCES, including debating wells, forcing substances through them into the formation. Dispersing minerals, and extracting them to the surface, which means that the degree of mineral extraction and shortening of reservoir mining time is reduced by controlling rock pressure and fluid movement and dispersed minerals in the reservoir , drilling of injection and production wells, the bottom holes of which are located in the plane of the reservoir, saboks the end sections of the bottom holes of these wells, drilling at least one additional well whose bottom is located in the formations between the injection and production wells, not intersecting the latter and the recovery between them, fill the injection production / wells and the recovery between them with an inert liquid at a pressure not less than the rock pressure of the host rock formations, displace the substances into the secondary well. amount, which provides treatment of the formation between the drilled wells, then pumped into the injection or additional well a thickened fluid with a specific gravity, a large specific gravity about a fossil, but smaller specific weight of interfering rocks, after which a mixture of this fluid and a dispersed mineral is extracted through a production well. 2. The method according to claim 1, which is based on the fact that the wellhead pac-f C "is assumed to be a dip in the reservoir, starting with a production well, while the bottom hole is along the strike of the reservoir, and the bottom of the drilling well goes in the same direction, but at an angle to the strike line in the direction of the reservoir dip. 3. The method according to paragraphs 1 and 2, which means that the injection and production wells of the drill t to the intersection with the previously developed space of the reservoir 4. The method according to claim 1, which is - 00 y and that the wellhead is located tyranny of the reservoir, and their bottom holes pass along the dip of the reservoir. 5. A method according to claim 1, characterized in that the washed liquid is pumped into an injection well through a pipeline that passes to the end of the specified well. 6; The method according to claim 1, characterized in that during the injection period

Description

dispersing substances into an additional well are periodically injected with an inert fluid into the injection well and pumping it out of the production well. 10 858 7. The method according to claim 1, that is, so that the dispersing substances are injected into the reservoir under pressure, providing hydraulic fracturing or 1 reservoir discharge.

one

The invention relates to mining and can be used in the mineless mining of solid minerals, such as coal, by dispersing it.

There is a method of coal production using borehole monitors l 3,

However, the method is characterized by laboriousness and loss of coal in its entirety.

There is a known method for the extraction of minerals, which includes the supply to the fractured reservoir of a heavy liquid for the extraction of mineral-enriched rock particles.

The disadvantage of this method is the necessity of preliminary preparation of the deposit.

The closest to the proposed in essence and the achieved result is a method that includes drilling wells, pumping minerals dispersing Mineral through them into the formation, and removing the latter to the C 3 surface

The disadvantages of this method are the large laboriousness of work, low speed of mining due to the low speed of heterogeneous physico-chemical reactions between coal and dispersing chemical reagent, large losses of mineral resources due to low speed of development of deposits and intensive displacement of host rocks.

The purpose of the invention is to increase the extraction of minerals and reduce the time needed to develop the deposit by controlling rock pressure and fluid flow and dispersed minerals in the reservoir.

The goal is achieved in that according to the method, including drilling wells, injecting minerals dispersing minerals through them, and removing the latter to the surface, drilling injection and production wells, whose bottom holes are located in the formation plane, bridges the end sections of the bottom holes of these wells , at least one additional well is drilled, the bottom of which is located in the plane of the formation between the wells of the injection and production wells, does not intersect the latter and connect between them, fill injection wells, production wells and the connection between them with an inert fluid at a pressure not lower than the rock pressure of the rocks enclosing the reservoir, inject an additional dispersant in an additional well in an amount that provides treatment of the formation between the drilled wells, then injected into the injection well or an additional well fair weight, greater specific gravity of the mineral, but less than the specific weight of the host rocks, after which a mixture of this fluid is extracted through the production well spine and dispersed mineral.

The wellhead is positioned along the dip of the reservoir, starting from the production well, while the bottom of the injection well passes along the strike of the formation, and the bottom of the production well passes in the same direction but at an angle to the strike line in the direction of the dip.

In addition, the injection and production wells are drilled to the intersection with the previously developed reservoir space.

The mouth of the wells is located along the strike of the formation, and their downhole faces pass along the dip of the formation.

The wetted fluid is pumped into the injection well through a pipeline that runs to the bottom of the bottom of the indicated well.

In addition, during the injection of dispersing substances into an additional well, periodic injection of an inert fluid is made and the pump is pumped out. At the same time, dispersing substances are injected into the formation under pressure, which provides hydraulic fracturing or pneumatic fracturing. FIG. 1 shows a diagram of the proposed method with the location of the opening sites on the strike line (vertical section through the production well); in fig. 2 shows section A-A in FIG. one; Fig. 3 - the same, but in the process of excavation of solid minerals; in fig. 4 shows the scheme of the proposed method with the location of the opening sites on the dip line (axonometric section in the plane of the wells). The production site consists of the production wells 1 and the input well 2, the reservoir 3 of the solid mineral (the place of opening the production well is 4) and passing in the plane of the reservoir (the area of the production well passing in the plane of the reservoir is indicated as 5), connecting 6 the end sections of the inlet and production wells located in the plane of the reservoir, additional wells 7–9 for injection of dispersant substances passing in the plane of the reservoir between the inlet and production wells and not intersecting the inlet, extractive wells us and sboyka, conduit 10. The gob formed when extracting solid minerals is designated. 11. The arrows indicate the direction of movement of the fluid with a specific gravity, a greater specific gravity of the solid fossil but less specific gravity of the host rocks. The method is carried out as follows. A production well 1 and an injection well 2 are drilled, revealing the developed section of the formation 3 and passing in the plane of the formation. In one implementation of the method, the autopsy sites are located on the strike line of the field, and portions of wells located in the plane of the reservoir are drilled down the field (Fig. 1-3). Then, 6 end sections of the inlet and production wells are connected, arranged in the plane of the formation. Firing is performed by fire, electrothermal method, rhenium of a connecting inclined-horizontal well, etc. At least one additional well 7-9 is drilled at 310118684 in the inlet well of the inlet, the production well. wells and not intersecting the inlet, production well and their connection, seal the inlet and production wells, fill the inlet, production wells and their assembly with liquid and maintain excess fluid pressure, counteracting the development of rock pressure of the host rocks and clamping the input. production wells and their svyki. Solid matter is discharged into the reservoir of solid mineral through additional wells, which disperse solid minerals in quantities that ensure treatment of the developed section of the field located between the input and production wells and their connection. Depending on their phase state, injection into the reservoir of di-dergents is carried out in the hydrodissection or pneumo-dissected reservoir mode, during which treisna develop in the developed part of the deposits. Dispersants, penetration into cracks, macropores and micropores of a solid mineral, cause its destruction, and at the initial moments of time dispersion occurs along the boundaries of cracks and macropores, and then spreads deep into blocks of solid minerals. So that the field of the field outside the development site is not exposed to destruction under the action of dispersing agent, injecting dispersant substances into the additional well periodically inert fluid is injected into the injection well and out of the complementary well, which results in the dispersing agent from the injection, production well and their assembly and eliminates the possibility of dispersing the substance outside the developed area. When the developed area of the field is transferred into loose cocTOsmHe under the action of dispersing agents, it is pumped into the injection well or injection and additional wells with a specific gravity, a greater specific gravity of the solid mineral, but a smaller specific gravity of the surrounding rocks, and a mixture of this liquid and crushed solid is extracted. fossil through a production well. Fluid flow, passage through the injection well.

connection and production well, erodes the solid mineral, which has been transferred to the state, to be moved to the production well. In a production well, the mineral is floated and released to the surface by a flow of fluid.

Since solid minerals can also be poured in the input well, in order to avoid the formation of a counter-flowing liquid and a mineral in the injection well, a heavy liquid is injected into it through a conduit, the outlet of which is located at the end of the borehole. The surfaces of the clearing flank on which erosion of the loosened solid mineral occurs, in this case, will be the tailing of the end sections of the injection and production wells located in the plane of the reservoir, and the section of the production well located in the plane of the reservoir (Fig. 2). Moving the output section of the pipeline upward along the injection well as the loosened mineral is extracted, it is dredged from the entire developed section of the field located between the input production well and their connection. The injection of additional fluids into additional wells with a specific gravity, a greater specific gravity of the solid mineral, but a smaller proportion of the host rocks, accelerates the size of the loosened mineral and spread it to the surface. In the proposed method of development of stratum deposits of solid minerals, there is no need to control the roof of the mining output in the process of excavating the solid mineral. In the developed space, the enclosing rocks are displaced and, since the specific gravity of the fluid filling the production is less than the specific weight of the enclosing rocks, the spontaneous collapse of the roof (position 11 in Fig. 3). Crashing) does not interfere with the process of excavation of loosened mineral by scouring it and carrying it out with a fluid with a specific weight greater than the specific gravity of the solid mineral (Fig. 3), as the mining face moves from the depth of the reservoir to the place of mining borehole.

In the second implementation of the method, the opening sites are located on the dip line with the location of the opening site by the injection well lower than the production one, the input well section located in the plane of the reservoir is drilled along the field, and the production well site located in the plane of the reservoir at a certain angle to the strike line, so that the largest distance between the sections of the inlet and production wells located in the plane of the reservoir, measured along the dip line, was on the line connecting n guide space autopsies. The production well, located in the plane of the reservoir, is located on the same side of the line connecting the opening sites as the injection well section (Fig. 4). The location of a section of a production well located in the plane of the formation at an angle of ° C to the strike line (Fig. 4) facilitates the transportation of the crushed mineral in this section of the well due to the effect of pushing force and the possibility of spontaneous movement of the emerging mineral from the reservoir to the site of the reservoir. In the second implementation of the method, in further development of the field, an injection well site located in the plane of the reservoir along its strike and a production well site located in the plane of the reservoir under the slope to the strike line is crossed to the intersection with the developed space formed in the previous production cycle, with In this way, the overfilled space serves as a pool of injection and well boreholes. The second implementation of the method has advantages over the first one: with further development, there is no need to carry out the coupling of the injection and production wells, it is also possible to completely excavate solid minerals over considerable areas without leaving any coal. The disadvantage of the second implementation as compared to the first one is the necessity of drilling inclined bore holes. PRI me R. At a depth of 300 m, a coal bed with a thickness of 3 m is being developed. The inlet and production wells are drilled, their end sections are assembled and three additional wells are drilled (Fig. 2). The length of the sections of the input and production wells located

in the plane of the reservoir, 1OO m each, the connection length is also 1OO m. The length of the additional chkvanosh areas located in the plane of the reservoir is 75 m each.

After drilling and assembly, they are sealed, placed into the inlet well pipeline ((| 2), the inlet well, the coupling and the production well are filled with fluid, the fluid overpressure is maintained, coal dispersing substances are pumped into the coal bed through an additional well for example, an aqueous solution of methylamine, in amounts that sintering the loosening of the seam developed by the reservoir, and then inject a fluid into the input well with a specific gravity, a greater specific gravity of coal, but less than the specific gravity of the core x rocks, such as clay slurry, and extract a mixture of crushed coal and this fluid from the production well.

The application of the proposed method allows you to completely remove the coal from the developed area.

The proposed method of developing reservoir deposits of solid minerals in comparison with the known provides a reduction in the volume of drilling workings by 3-5 times and, accordingly, a reduction in the time spent on preparing and excavating the developed area; an increase in the degree of extraction of solid mineral by 20-4%; reduces labor intensity, accelerates the pace of development and development of the field and leads to a more complete extraction of solid minerals.

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Claims (7)

1. METHOD FOR DEVELOPING PLASTIC DEPOSITS OF SOLID USEFUL MINERALS, including Drilling wells, injecting substances dispersing minerals through them into the formation, and extracting the latter to the surface, characterized in that, in order to increase the degree of extraction of minerals and shortening the life of the formation by controlling rock pressure and the movement of fluids and dispersed fossil in the reservoir, drill the injection and production wells, the faces of which are located in the plane of the reservoir, produce a malfunction the end sections of the faces of these wells, drill at least one additional well, the bottom of which is located in the plane of the reservoir between the faces of the injection and production wells, without intersecting the latter and the failure between them, fill the injection and production wells and the failure between them with an inert fluid at a pressure not less than the rock pressure of the rocks enclosing the formation, the dispersants are injected into the additional well in an amount that ensures the treatment of the formation between drilled wells, then in the heel atelnuyu or more weighted well bore fluid is injected with a specific gravity greater than the specific gravity useful CSIS a share, but a smaller proportion of the surrounding rocks, and then through the production wells is removed and the liquid mixture was dispersed mineral. 2. The method according to π. 1, characterized in that the wellheads of the races are assumed to be according to the dip of the formation, starting from the production well, while the bottom of the injection well passes along the strike of the formation, and the bottom of the production well passes in the same direction, but at an angle to the side of the strike line formation fall. 3. The method according to PP. 1 and 2, which consists in the fact that the injection and production wells are drilled before intersecting with the previously worked out space of the formation * 4. The method according to π. 1, characterized in that the wellhead is located along the strike of the formation, and their faces pass along the fall of the formation. 5. The method according to π. 1, characterized in that the weighted fluid is pumped into the injection well through a pipeline extending to the end of the bottom of the specified well. > 6; The method according to π. 1, characterized in that during the period of dispersant injection into an additional well, an inert liquid is periodically pumped into the injection well and pumped out of the production well. 7. The method according to π. 1, due to the fact that dispersing substances are injected into the formation under pressure, providing hydraulic fracturing or pneumatic fracturing of the formation.