RU2069753C1 - Method for preparation of double faces - Google Patents

Abstract

FIELD: mining; applicable in underground mining of mineral beds with unstable roof rocks. SUBSTANCE: method for preparation of double faces includes determination of rational length of double face, driving of intermediate development spaced from worked-out space at distance equalling rational face length with subsequent determination of areas of zone with unstable roof rocks within developed pillars. The value of ratio of total area of zones with unstable roof rocks within the pillar worked by the second face is used to determine the length of the second face. EFFECT: higher efficiency. 3 cl, 1 dwg

Description

 The invention relates to mining and can be used in underground mining of reservoir deposits, mainly coal, using dual (or twin) lava development systems.

 Known methods for the preparation of twin lavas, including determining the rational length of the lava, conducting preparatory workings at the boundaries of the excavation site mined by dual lavas, and two intermediate preparatory workings in the middle part of the excavation site (Andrushkevich S.G. et al. Technology of underground development of reservoir deposits. M Nedra, 1972). The disadvantages of this method are significant losses of minerals in the pillars, large volumes of conducting and maintaining preparatory workings.

 There is a method of preparing double lavas (A. Burchakov et al. Technology of underground mining of stratified mineral deposits. M. Nedra, 1983, p. 254,260), which includes determining the rational length of lavas, conducting precast preparatory workings at the borders of the prepared excavation site, and intermediate preparatory development. The length of the doubled lavas is assumed to be the same. Lavas are practiced while maintaining the optimal distance between them.

 The disadvantages of this method are the significant negative mutual influence of twin lavas during mining of formations with unstable rocks of the roof having zonal distribution. The mutual influence of lavas in these conditions, as a rule, leads to production losses, uneven flow of goods from the site and an increase in cost.

 The aim of the invention is to increase the technical and economic indicators of the treatment excavation when mining mineral strata with unstable roof rocks having a zonal distribution.

 To achieve this goal, determine the rational length of the first lava, at a distance from the worked out space, equal to the rational length of the first lava, undergo intermediate preparatory development. Determine the area of zones with unstable rocks of the roof, which calculate the total area of zones with an unstable roof within the pillars, prepared for mining the first and second lava. The ratio of the total area of zones with unstable roof rocks within the column worked out by the first lava is found to the total area of zones with unstable roof rocks within the column worked by the second lava. The magnitude of this relationship is judged on the length of the second lava.

When mining thin and medium thickness strata with angles of incidence up to 30 ^o with a ratio of the total area of zones with unstable roof rocks more than 1.3 1.4, the length of the second lava is 10 15% longer than the length of the first lava.

When mining thin and medium thickness strata with dip angles of up to 30 ^o with a ratio of the total area of zones with unstable roof rocks less than 0.7-0.8, the length of the second lava is 15-20% less than the length of the first lava.

 The drawing shows the worked out part of the mine field, top view.

In the drawing, ABCD indicates a mining column, mined by the first lava N 1; ЕАДМ excavation column mined by the second lava N 2; 3 - intermediate preparatory development; 4, 5 preparatory workings completed at the boundaries of the excavation site; 6, 7 split furnaces, respectively, the first (N 1) and second (N 2) lavas; l _{1 the} length of the first lava; l _{2 the} length of the second lava.

 Unstable roof areas are shaded.

 One of the factors that have a significant impact on the technical and economic indicators of dual lavas is the ratio of the speeds of their movement. The maximum values of the clearing excavation are achieved when the speeds of movement of the double lavas are equal, which is relatively easy to achieve when mining excavation columns, characterized by approximately the same stability of the rocks of the immediate roof.

 When working with twin lavas of sections of the mine field, within which there are areas with unstable roofs, it is almost impossible to ensure the same speed of movement of twin lavas using known methods for preparing twin lavas without loss of production, violation of the uniformity of cargo flow or increase in the cost of maintaining an intermediate drift.

 The difference in the velocities of the double lavas leads to a decrease or to an increase in the distance S (see the drawing) between the lavas. With an increase in this distance, the costs of repairing the section of the intermediate drift between the lavas, which is in the most difficult maintenance conditions, sharply increase. Repair work in this technologically busy section of the drift leads to additional downtime of lava and loss of production.

 With a decrease in the distance S between the lavas at their end sections adjacent to the intermediate drift 3 (see the drawing), the degree of disturbance of the roof rocks by cracks of operational origin increases, which leads to an increase in the intensity of collapse of the roof rocks and, consequently, to additional downtime associated with the working faces associated with with cleaning the breed and laying out the stands over the lining sections.

 To ensure the same speed of movement of the double lavas and maintain the optimal distance S (see the drawing) within acceptable limits, using known methods, one of the lavas is periodically stopped, which is worked out under more favorable conditions due to the "unstable roofing rocks" factor. This event leads to loss of production and deterioration of the roof when the lavas are turned on after downtime.

 In the proposed method, determine the rational length of the lava for the given geological conditions, then undergo intermediate preparatory development at a distance from the worked out space equal to the rational length of the lava. By the rational length of the lava here is meant the length of the lava at which the minimum total costs associated with the preparation and development of one column in the absence of zones with unstable roof rocks are ensured. Thus, one of the lavas (the first lava) will have a rational length, regardless of the presence of zones with an unstable roof within the prepared columns. This, combined with other essential features, makes it possible to achieve the maximum feasibility for the given conditions of the technical and economic indicators of the treatment excavation within the mining section (two lavas enter the mining section).

 Determination of the total area of zones with an unstable roof within double columns and finding the value of the total area of zones with an unstable roof within the ABCD column (see drawing) worked out by the first lava to the total area of zones with unstable roof rocks within the EADM column processed by the second lava , allows you to judge the length of the second lava, taking into account the presence of zones with unstable rocks of the roof within double columns.

In the General case, when the magnitude of this ratio is greater than 1, the length of the second lava l ₂ take more than the length of the first lava l ₁ . When the value of this ratio is less than 1 take l ₂ <l ₁ . Those. a column with more unfavorable conditions on the factor of "unstable roofing" is worked out by a lava of shorter length. This allows you to ensure the same speed of moving lavas without forced stops of one of them.

As a result of mine research, it was found that when mining thin and medium thickness strata with an angle of incidence of up to 30 ^o with a value of the specified ratio of more than 1.3 • 1.4, the length of the second lava is 10-15% longer than the length of the first lava.

When developing thin and medium thickness strata with dip angles of up to 30 ^o C with a ratio of the total area of zones with unstable roof rocks less than 0.7-0.8, the length of the second lava is 15-20% less than the length of the first lava.

 The areas of unstable roofing zones within the prepared excavation columns can be determined using well-known geophysical methods or geological exploration methods after the intermediate preparatory excavation.

 Using the inventive method allows to reduce the loss of mining, to ensure the uniformity of cargo flow from the lavas, to reduce the cost of maintaining an intermediate drift in the area between the twin lavas.

In the deep mines of the Eastern region of Donbass, an increase in the total productivity of double lavas when applying the proposed method reaches 10-15%
An example of a specific implementation in the mine. 50th anniversary of October A.O. Gukovugol.

The layer L ₆ with a thickness of 1.3 m is being worked out, the angle of incidence of the layer is 12 ^o C.

 Dual Lava Formation System along strike. The length of the excavation columns is 1500 m. The rational length of the lavas is 200 m, the optimal distance between the lavas is 20 30 m.

 Different speeds of movement of twin lavas of the same length leads to: loss of production (up to 25%), which is associated with the "containment" of the lava, working out a column with a smaller area of zones with an unstable roof; loss of production (up to 10%) when reducing the distance between lavas to a value less than 10 12 m; to increase the cost of maintaining the section of the intermediate development between the twin lavas (3-4 times or more).

 Within the area of the mine field being prepared for mining, there are zones with unstable roof rocks, the dimensions of which are up to tens of thousands of square meters. The rocks of the immediate roof within these zones are represented by clay or sand-clay shales, the collapse of which occurs in many cases when the roof is exposed, associated with the excavation of a strip of coal. Zones are randomly located.

 Site preparation (two columns) is carried out in the following sequence.

 At a distance of 200 m from the worked-out space, an intermediate drift passes.

Additional exploration of the composition of the roof rocks within the prepared columns using known geophysical methods is carried out. At the same time, an intermediate drift is used to place the equipment. As a result of additional exploration, the areas of areas with an unstable roof are established. These areas are summarized to determine the total areas of zones with an unstable roof within each of the prepared posts. The total area of the zones within the first column is 150x10 ³ m ² , within the second column 100 x 10 ³ m ² . The ratio of the total area of zones with an unstable roof within the first column and the total area of zones within the second column is 1.5.

 In accordance with paragraph 2 of the claims, the length of the second lava is 10% greater than the length of the first lava. Those. the length of the second lava is 220 m.

 Different lengths of lavas provide approximately the same average speed of lava movement, which under the conditions under consideration allows to reduce production losses associated with the mutual influence of lavas by 1.5 2.0 times and to reduce the cost of maintaining an intermediate drift in the section between lavas by 3-4 times Pillar mining time.

Claims (3)

 1. The method of preparation of dual lavas, including the determination of rational lengths of lavas, the conduct of local preparatory workings at the borders of the prepared excavation site and the intermediate preparatory workings, characterized in that when mining mineral formations with unstable roof rocks having a zonal arrangement, determine the rational length of the first lava , at a distance from the worked out space, equal to the length of the first lava, they pass the intermediate preparatory development, determine the area di zones with unstable roof rock within the prepared double pole, the magnitude of the total area ratio with unstable roof rock within executed by the first column to the lava rocks with fragile zones of the total area within the roof pillar executed by the second lava, determine the length of the second lava. 2. The method according to claim 1, characterized in that when developing thin and medium thickness strata with dip angles of up to 30 ^o with a ratio of the total area of zones with unstable roof rocks more than 1.3 1.4, the length of the second lava is 10-15 % more than the length of the first lava.  3. The method according to PP. 1 and 2, characterized in that when the ratio of the total areas of zones with unstable roof rocks is less than 0.7 0.8, the length of the second lava is 15-20% less than the length of the first lava.