RU2327035C2 - Layer excavation method of mineral resources - Google Patents

Abstract

FIELD: mining engineering.

SUBSTANCE: method includes carrying out of face entry 11,13, main 1-4 and divisional 5-10 development workings, delineating of mineral resources blocks, assembling of scouring mechanised systems in face entries 11, consistent pairwise mineral resources blocks debugging with long faces N.1, N.2 and dismantling of scouring mechanised systems in dismantling chambers 12. Face entry of the second long face 13 deepen in line of dismantling chamber 12 of the first long face at first stage. At the beginning, by the moment of broken working termination in first long face deepens the area of the second long face, and located from side of mineral resources virgin ground. After termination of broken working in the first long face, face entry of the second long face is deepen till the mined-out space, appeared while debugging of the first long face. At that length of face entry unit of the second long face, debugged after broken working termination in the first long face, is taken more than boost band width, appearing in front of the first long face bank.

EFFECT: costs decreasing connected with accomplishing of assembling-dismantling works, as well as a time cutting of their accomplishing and safety improving.

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Description

The invention relates to mining and can be used in underground mining of mineral deposits by lavas equipped with treatment mechanized complexes.

There is a method of developing mineral deposits (Auth. Certificate. No. 1434109, Bull. 40, 1988. Authors: Zubov VP, Lazchenko KN, Melkov AD, Ivanov AA), including the separation of mining section of the mine field on the pillars of minerals, the development of which is carried out by lavas. For the preparation of mineral pillars for excavation, preparatory workings take place. After completion of the pillar mining, the treatment equipment is dismantled in the dismantling furnace.

The disadvantages of this method are the significant cost of dismantling, the long duration of their implementation and the increased risk of labor for miners associated with an increased degree of destruction of roofing rocks and rock outfalls in dismantling chambers.

A known method of developing mineral deposits using mechanized complexes (RF Patent No. 2101497 for the invention "Method for the development of mineral deposits". Authors: VP Zubov, AB Sokolov, AE Kononova, VV Karin , Bull. No. 1, 1998), adopted as a prototype method. This method includes conducting split furnaces, main and local preparatory workings, contouring the columns of minerals, installing mechanized sewage treatment plants in split furnaces, pair-wise mining of mineral pillars with lavas, and dismantling mechanized sewage treatment plants in dismantling chambers.

The disadvantages of this method are the significant costs associated with the dismantling of the mechanized complex, the long duration of the dismantling work and their increased danger. These shortcomings are largely due to the high degree of destruction of the rocks of the immediate roof of the reservoir in the section of the split furnace of the second lava adjacent to the mined space formed during mining of the first lava, as well as at the junction of the split furnace and the dismantling chamber. The increased degree of destruction of rocks of the immediate roof in a split furnace of the second lava and at its interface with the dismantling chamber is associated with the effect of increased stresses arising in front of the face of the first lava. The negative effect of increased stresses on the condition of the rocks of the immediate roof begins to appear when the first lava approaches the place of its dismantling at a distance less than the width of the zone of increased stresses (zone of reference pressure) arising in front of its face.

As a rule, when using the known prototype method during periods of approach of the first lava to the place of its dismantling and when performing dismantling and installation work, collapse of the roof rocks is observed in the section of the split furnace adjacent to the mined space formed during mining of the first lava, as well as at the interface split furnace and dismantling chamber. To ensure the safety of mining in these places, additional support is installed, which leads to a rise in the cost of installation and dismantling works and an increase in the time of their implementation.

The technical result of the proposed method is to eliminate the disadvantages of the known method, namely reducing costs associated with the implementation of dismantling and installation works, reducing the time it takes to complete dismantling and installation works and increasing their safety.

The technical result is achieved by the fact that in the method of developing mineral deposits, split furnaces are carried out, the main and local preparatory workings that outline the mineral pillars, mechanized treatment plants are installed in split furnaces, sequential pairwise mining of mineral pillars by lavas and dismantled treatment mechanized complexes in dismantling chambers.

According to the invention, the split second lava furnace passes in line with the dismantling chamber of the first lava in two stages. Initially, before the cessation of treatment in the first lava, the section of the second lava split furnace located on the side of the untouched mineral mass passes through. After the cessation of treatment operations in the first lava, the split furnace of the second lava passes to the mined space formed during the mining of the first lava. In this case, the length of the section of the split furnace of the second lava, which is passed after the termination of the treatment works in the first lava, is assumed to be greater than the width of the zone of increased stresses arising in front of the face of the first lava.

The essence of the proposed method for the development of mineral deposits is illustrated by the scheme shown in the drawing.

The drawing shows a diagram explaining the relative position of the columns being mined and prepared for mining, as well as the dismantling chamber of the first lava and the split furnace of the second lava.

In the drawing: 1-4 - the main preparatory workings; 5-10 - local preparatory workings; 11 - split furnace of the first lava (No. 1), working off the column ABCD; 12 - dismantling chamber of the first lava; 13 - split furnace of the second lava (No. 2), designed to test the prepared column DCMN; l ₁ - the length of the first lava; l ₂ - the length of the second lava; and - the length of the section of the cutting furnace 13 of the second lava, walked until the cessation of treatment in the first lava; b is the length of the section of the cutting furnace 13 of the second lava, passed after the cessation of treatment in the first lava.

The method is as follows. A split furnace 11 is carried out, the main 1-4 and precinct 5-8 preparatory workings contouring the column ABCD. In a split furnace 11, a mechanized treatment complex is mounted. After mining the first lava (No. 1) of the ABCD column, the mechanized treatment complex is dismantled in the dismantling chamber 12. The main 1–4 and precinct 9–10 preparatory workings that outline the DCMN column are carried out. Local preparatory development 5 is reused. The split furnace 13 of the second lava passes in two stages in line with the dismantling chamber 12 of the first lava. Initially, until the cessation of treatment in the first lava, a section of a cutting furnace 13 of length “a” is located, located on the side of an untouched array of minerals. After the cessation of treatment works in the first lava, the sinking of the split furnace 13 is completed. It passes to the mined space formed during mining of the first lava. The length of section "b" of the cutting furnace 13, which is passed after the cessation of cleaning operations in the first lava, is taken to be greater than the width of the zone of increased stresses that occurs in front of the face of the first lava.

Carrying out section “b” of the second lava cutting furnace after the cessation of cleaning operations in the first lava allows reducing the negative effect of increased stresses in front of the first lava face on the condition of the rocks of the immediate roof in the cutting furnace 13 in section “b”, as well as at the joint furnace 13 and dismantling chamber 12 (point C, see drawing).

The width of split furnaces and dismantling chambers when using, for example, mechanized complexes of the Joy type is 8.5–9.0 m. Ensuring a stable state of production with such a width while it is in the zone of high stresses that arise in front of the face of the first lava (method -prototype), is associated with significant additional costs, loss of time for the installation of auxiliary support and an increased risk of labor for miners associated with the collapse of the roof rocks.

When the length of section “b” of the cutting furnace 13 is greater than the width of the zone of increased stresses that occur in front of the face of the first lava, the negative effect of increased stresses on the state of the rocks of the immediate roof of the formation in section “a” of the cutting furnace 13, which is passed until the cessation of treatment in the first lava .

The consequence of the reduction of the negative influence of the first lava on the condition of the rocks of the direct roof at the location of the split furnace 13, as well as on the conjugation of the split furnace 13 and the dismantling chamber 12, is an increase in the maximum allowable exposure of the roof in these workings when performing dismantling and installation works. This allows to reduce the costs associated with the construction of additional support and cleaning of collapsed roof rocks during the dismantling of the mechanized complex in the dismantling chamber 12 and its installation in the split furnace 13. This reduces the overall duration of the dismantling and installation work and increases the safety of miners.

The width of the zone of increased stresses that occur in front of the face of the first lava is determined in each case using well-known methods of mine, laboratory or analytical studies.

Using the proposed method for the development of mineral strata allows 10-20% to reduce the cost of dismantling and installation work and the duration of their implementation. At the same time, by reducing the likelihood of collapse of rocks of the direct roof in the dismantling chamber and the split furnace, the safety of miners is increased.

The inventive method is rational to use when mining mineral strata (coal, salt, etc.) with dip angles of up to 30-32 ° by lavas equipped with mechanized complexes.

The maximum effect when using the proposed method is achieved when mining powerful (more than 3.5 m) coal seams in the immediate roof of which rocks (mudstones, siltstones) with relatively low strength characteristics (up to 30-40 MPa) lie. With increasing depth of mining operations, the effectiveness of the use of the proposed method increases.

Claims (1)

A method of developing mineral strata, including conducting split furnaces, main and local preparatory workings, contouring the columns of minerals, installing mechanized sewage treatment plants in split furnaces, sequential pair mining of mineral columns with lavas and dismantling mechanized sewage treatment plants in dismantling chambers, characterized in that the second lava split furnace is in line with the dismantling chamber of the first lava in two stages, initially until of cleansing operations in the first lava, the section of the second lava cutting furnace located on the side of the untouched mineral array passes, after the cessation of the cleaning operations in the first lava, the second lava cutting furnace passes to the mined space formed during mining of the first lava, while the length of the section of the second furnace is second lava, passed after the cessation of treatment in the first lava, take more than the width of the zone of increased stress arising in front of the face of the first lava.