RU2305188C2 - Underground mineral mining method - Google Patents

Abstract

FIELD: mining, particularly underground mining of flat-lying mineral seams in areas characterized by disjunctive geological displacement.

SUBSTANCE: method involves dividing mineral seam into columns; preparing the columns by paired developing entries along with mineral pillars establishing between the developing entries; excavating supplementary entries between developing ones; cutting the columns with long-wall faces with the use of powered mining complexes; gobbing developing entry adjoining long-wall face behind long-wall face during column cutting and repeatedly using the second development entry. The columns are arranged along geological displacement areas. Developing entry to be gobbed during column cutting and reusable one are formed from opposite geological displacement sides out of zone having increased fissure density developed near geological displacement. As mineral seam zone characterized by fold geological displacement is cut reusable development entry is excavated in hanging wall. As mineral seam zone characterized by overfold geological displacement is excavated reusable developing entry is cut in underside wall of overfold displacement.

EFFECT: increased mining safety and decreased coal losses.

4 dwg

Description

The invention relates to the field of mining and can be used in underground mining of shallow layers of minerals, mainly coal and salt, in areas with disjunctive (discontinuous) geological disturbances.

Known methods of underground mining of mineral deposits (B.F. Bratchenko, M.I. Ustinov, L.N. Gapanovichi and others. Methods of opening, preparation and development systems for mine fields. - M .: Nedra, 1985, p. 85 and with .99), including the separation of the reservoir into mineral columns, the preparation of mineral pillars by single preparatory workings, the development of pillars, minerals by lavas using treatment mechanized complexes.

The disadvantages of these methods are the difficulty of ventilating single preparatory workings during their excavation, significant costs for maintaining preparatory workings and installation and dismantling work in lavas, when developing powerful gas-bearing strata of minerals in areas with disjunctive geological disturbances such as uplifts and discharges.

A known method of underground mining of mineral deposits (A. S. Burchakov, N. K. Grinko, A. B. Kovalchuk. Technology of underground mining of reservoir mineral deposits. M: Nedra, 1978, p. 93-94 and p. 91 ), adopted as a prototype, including the separation of a mineral layer into columns, the preparation of pillars by paired preparatory workings with the remaining pillars of minerals between them, the holding of auxiliary workings between paired preparatory workings, the development of mineral pillars about lavas with the use of mechanized sewage treatment plants, repayment of lava during the development of a pillar of a preparatory mine adjacent to the mined column, and reuse of the second preparatory mine.

The disadvantages of this method are the large operational losses of the mineral, the significant costs of maintaining the preparatory workings and installation and dismantling work in the lavas during the development of powerful gas-bearing formations in areas with non-transferable mechanized complex disjunctive geological disturbances such as faults and faults.

When using the known method (prototype) between paired preparatory workings leave the pillars of the mineral with a width of more than 5-6 removable thickness of the reservoir. Operational losses in these pillars reach 20% or more of the carrying reserves of the excavation site. Preparatory workings are negatively affected by reference pressure, which is formed both in front of the lava and at the marginal parts of the mineral massif, which results in significant maintenance costs. The high costs of installation and dismantling work in the lavas are associated with the need to dismantle the treatment equipment when approaching the lavas to geological disturbances that are not mechanized by the complex, conducting a split furnace for geological disturbance and installing the treatment equipment.

The technical result achieved by using the proposed method is the elimination of these disadvantages of the known prototype method, namely the reduction of operational losses of minerals, the cost of maintaining preparatory workings and installation and dismantling work in lavas during the development of powerful gas-bearing formations in areas with inoperable mechanized disjunctive complex geological disturbances such as faults and faults.

The technical result is achieved by the fact that the claimed method of underground mining of mineral strata in areas with disjunctive geological disturbances such as faults and faults includes dividing the mineral stratum into poles, preparing the columns with paired preparatory workings with the remaining pillars of the mineral between them, conducting between the paired preparatory workings of auxiliary workings, mining of pillars with lavas using treatment mechanized complexes, repayment of lava for the process improvement of production preparatory column adjacent to the column practiced and reuse second preparatory workings.

According to the invention, the columns are arranged along geological disturbances. The preparatory excavation repaid during the development of the pillar, and the preparatory excavation intended for reuse, pass from opposite sides from the geological disturbance outside the zones of increased intensity of cracks occurring near the geological disturbance. At the same time, during mining of mineral deposits in areas with geological disturbances such as discharges, preparatory development intended for reuse takes place in the hanging wing of the discharge, and during mining of mineral deposits in areas with disjunctive geological disturbances such as faults, preparatory development intended for reuse, pass in the lying wing of the throw-up.

The essence of the proposed method is illustrated by drawings.

Figure 1 shows a schematic diagram of a section of the reservoir (plan view) with disjunctive geological disturbances.

Figure 2 is a diagram illustrating cracks occurring in zones of influence of geological disturbances such as faults and the location of paired preparatory workings relative to the geological disturbance.

Figure 3 shows a schematic diagram of a geological disturbance such as reverse faults. Figure 4 shows a schematic diagram of geological disturbances such as discharges.

Thrust and fault are forms of discontinuous tectonic displacements of rocks. During uplift, the movement of rocks occurs along a crack inclined to the horizon. In this case, the rocks of the hanging wing (side) lying above the displacement surface move upward along it. (Mining. Dictionary. Publishing house. "Nedra" 1974, p. 55).

When dumping the rock of the hanging wing (side), lying above the displacement surface, move down.

In figures 1 and 2: ABCD - mined column of minerals; QWER - mineral column being prepared for mining; 1 and 2, 3 and 4, 5 and 6 - paired preparatory workings; 4 - preparatory development repaid for the lava in the process of working off the column ABCD; 3 - preparatory development, designed for reuse in the development of the QWER column; 7 - auxiliary preparatory development; 8 and 9 - the main preparatory workings (for example, main drifts with the horizontal method of preparing the mine field); 10 - disjunctive geological disturbances such as faults or faults; 11 - cracks occurring in zones of influence of geological disturbances; l ₁ and l ₂ - the width of the zones of increased intensity of the cracks 11 that occur near a geological disturbance; KL - line of formation strike; MN is the line of formation fall.

The method is as follows.

A layer of mineral within the mining area is divided into pillars. Preparation of mineral pillars for mining is carried out by conducting paired preparatory workings: 3 and 4 - in the preparation of the column ABCD; 5 and 6 - during the preparation of the QWER column. Between the paired preparatory workings leave the pillars of the mineral with a width of Z, along which the auxiliary workings pass 7. The columns of the mineral work out with lavas equipped with treatment mechanized complexes.

The columns (the longitudinal axis of the columns) are located along geological faults 10. As follows from the practical experience of underground mining of coal deposits, geological faults such as faults and faults are located in most cases at an acute angle to the line of formation fall (Fig. 1).

Preparatory workings 1, 3 and 4, as well as auxiliary workings 7, are designed to ensure the operation of the lava working off the ABCD pillar (ventilation, transport, moving people, etc.).

When working off the column ABCD, one of the paired preparatory workings (4) is extinguished, preparatory work 3 is saved for reuse when working off the QWER column.

Paired preparatory workings pass from opposite sides (Figs. 1 and 2) from a geological disturbance 10 outside the zones l ₁ and l _{2 of} increased intensity of cracks 11 arising near the geological disturbance.

When mining mineral deposits in areas with geological disturbances such as reverse faults (Fig. 3), preparatory excavations intended for reuse are held in the lying wing of the reverse fault.

When mining mineral deposits in areas with geological disturbances such as discharges (Fig. 4), reused preparatory workings take place in the hanging wing of the discharge.

Carrying out auxiliary workings 7 provides the possibility of transport and ventilation links between paired preparatory workings.

Justification of the materiality of the distinguishing features.

“The pillars are located along geological disturbances ...”

The fulfillment of this condition allows to reduce the cost of installation and dismantling in lavas, which is associated with a decrease in the number of remounts of lavas.

“The preparatory excavation that is repaid during the development of the pillar, and the preparatory excavation intended for reuse, pass from opposite sides of the geological disturbance outside the zones of increased intensity of cracks occurring near the geological disturbance ...".

The implementation of these essential features can reduce the operational loss of minerals in the pillars left between paired preparatory workings and reduce the cost of maintaining preparatory workings. The reduction in operational losses of minerals when using the proposed method (compared with the known prototype method) is explained by the fact that the development of mineral reserves in areas of the reservoir directly adjacent to disjunctive geological disturbances such as discharges and faults, as a rule, is not performed. These reserves are classified as off-balance.

“When mining strata of minerals in areas with geological disturbances such as discharges, preparatory development intended for reuse takes place in the hanging wing of the discharge, and when working out strata of minerals in areas with disjunctive geological disturbances such as faults, the preparatory mine intended for reuse in the lying wing of the throw-up ... ".

The specified location of the preparatory workings, designed for reuse, allows you to minimize the cost of maintaining paired preparatory workings throughout their life. Preparatory work, designed for reuse, has about two times longer service life than the preparatory work, repayable when working out the column: this work is used consistently when working out two pillars. For example, mine 3 is first used when mining an ABCD column, then when mining a QWER column. For a long time, mining designed for reuse is maintained near the edge of the mineral array that forms when the column is mined. The indicated circumstances predetermine higher requirements for the conditions of maintaining the preparatory excavation intended for reuse, in comparison with the preparatory excavation redeemed during the development of the column.

Achieving a positive effect is explained by the fact that with the accepted location of the preparatory mine designed for reuse, from the time it is held to maturity it is maintained in the area of the rock mass unloaded from the increased rock pressure. This area is formed near discontinuous geological disturbances: in the rocks of the hanging wing - during faults and in the rocks of the lying wing - during faults.

Compared with the known method of underground mining of mineral strata, the inventive method allows to reduce operational losses of a mineral by 10-20%, several times to reduce the total cost of maintaining paired preparatory workings, as well as the cost of installation and dismantling in lava.

The data necessary for the implementation of the proposed method, namely, the location of the boundaries of the regions of low stresses and increased intensity of cracks that occur near a geological disturbance, is determined using known methods as a result of mine, laboratory or analytical studies taking into account specific geological conditions of occurrence of the reservoir. The type of geological disturbance (fault or throw-up) is determined by geological services using well-known techniques.

The field of rational use of the proposed method

The inventive method is intended for use in underground mining of stratified mineral deposits (mainly salt and coal) in areas with disjunctive geological disturbances. Using the proposed method in the conditions under consideration allows: to reduce by 10-20% the operational loss of minerals, several times to reduce the total cost of maintaining paired preparatory workings, as well as the cost of installation and dismantling in lava.

Claims (1)

A method of underground mining of mineral strata, including dividing the mineral stratum into columns, preparing the pillars with paired preparatory workings, leaving the pillars of minerals between them, conducting auxiliary workings between paired preparatory workings, mining the pillars with lavas using treatment mechanized complexes, paying off lava during the process working out a pillar of a preparatory mine adjacent to the worked-out pillar and reusing e second preparatory excavation, characterized in that the columns are located along geological disturbances, the preparatory excavation redeemable during the development of the pillar, and the preparatory excavation intended for reuse pass from opposite sides of the geological disturbance outside the zones of increased intensity of cracks occurring near the geological disturbance , while mining mineral deposits in areas with geological disturbances such as discharges y intended for reuse pass in the hanging wing of the discharge, and during mining of mineral deposits in areas with disjunctive geological disturbances such as thrusts, preparatory development intended for reuse take place in the lying wing of the thrust.

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