RU2632606C1 - Method for depreservation steeply inclined nonactive sidewalls - Google Patents

Abstract

FIELD: mining engineering.

SUBSTANCE: open pit mining method of deep laying deposits with utilisation of temporarily nonactive walls it is formed at a steep angle close to the limiting one. At the upper mark level of the temporary nonactive wall a horizontal pad is left and divided into separate blocks along the length including ready (blasted) ones and the ones prepared for rock mass excavation when the wall is depreserved. The blocks are mined out with hydraulic back-shovel excavators mounted on the roof of the mined benches with loading rock mass into vehicles at the same level and transportation to surface via declines located on the end wall of the pit, the height mined benches and entries width are taken based on the working parameters of the excavators (depth and radius of excavating), benches development is carried out layer by layer from top to bottom. When advancing mining blocks of the active bench to the sufficient dimension and ensuring cargo and transportion connection with the surface, parallel development of the next bench starts, and so on until the entire temporarily nonactive wall is depreserved. To protect benches located below the temporary nonactive wall against rock falls a rock protection area is built at its base along the entire length, including a platform for placing the falling rock mass, an embankment on which a hydraulic backhoe-type excavator is placed, and a transport platform. The rock mass falling on the rock protection area is loaded with hydraulic excavator into vehicles and transported to the surface. As the mining operations go down the rock protection area is moved to lower elevations, providing the possibility to increase height of temporary nonactive wall and the preservation volumes.

EFFECT: decrease of current stripping coefficient within initial period of deposit development.

3 dwg

Description

The invention relates to the open development of deep mineral deposits using temporarily idle sides and can be used to optimize career space parameters.

There is a method of increasing the slope angles of the working boards, based on the phased development of deposits [1]. The essence of the method is the temporary preservation of individual ledges, in which the board is temporarily inoperative. Platforms of minimum width are left on conserved benches based on the convenience of their subsequent re-preservation. When the temporarily non-working side reaches the calculated height, the separation of its upper horizons begins, but at the same time, the height of the temporarily non-working side from the bottom continues to grow due to the ongoing deepening of the quarry. Thus, the temporarily idle side section “slides” along the contour of the stage. Similarly, areas of temporarily idle side formed on the contour of the subsequent stages of development are worked out. The economic efficiency of the method is achieved by reducing the current stripping ratio by increasing the resulting slope angle of the working side. At the same time, efficiency increases with an increase in the angle of inclination of temporarily idle sides. In large quarries, the volume of canned overburden can reach several tens of millions of cubic meters with a conservation period of 10 years or more.

However, this method of increasing the slope angles of the working sides has a significant drawback, namely, that the spacing of the upper horizons of the temporarily idle side is accompanied by the ejection of rock mass during blasting. As a result, with a sufficiently steep angle of slope of the temporarily idle side, all of it can be completely covered with blasted rock mass. This excludes the possibility of placing cutting openings on sections of the temporarily idle side and does not provide the conditions for safe mining operations when lowering the working horizons to the temporarily inoperative position. Such negative phenomena are avoided by the fact that a temporarily idle side is formed with sufficiently wide berms, which make it possible to place an ejection of blasted rock mass at one or two horizons. But this leads to a flattening of the resulting slope angle of the working side of the quarry and to an increase in the current stripping ratio in the initial period of the quarry.

Of the known methods of open-pit mining of mineral deposits, including the formation in the working zone of a quarry of ledges of a temporarily idle side, spacing of the upper horizons of a temporarily idle side simultaneously with its formation by bringing it into a temporarily idle position below the working horizons, is a method characterized in that at the horizons temporarily idle side barrage shafts are sprinkled to catch rockfall at intervals of height equal to the height of the sections temporarily not working side, and in the permanent or temporarily idle side of the quarry, transport bermas are arranged on the horizons of the barrage shafts, from which there are ramps to the lower working horizons within a depth interval equal to the height of the temporarily idle side section [2], [3].

The disadvantage of this method is the need to flatten out a temporarily idle side for the device of transport berms and platforms, platforms with barrage shafts and interrupt the cargo transportation between sections of the temporarily idle side when it is re-mothballed, and the device of the barrage shafts does not ensure the safety of work when re-conservation of pillars and work on working horizons due to the expansion of stones. Interruption of cargo transportation links between sections in depth during re-conservation of the side leads to the need for the construction of additional exits on the working board and its flattening. At the same time, solving the problem of opening through the removal of opening workings to the neighboring part of the working area with normal working sites and the construction of connecting transport sites leads to an increase in current overburden ratios and additional costs for developing the field.

The aim of the present invention is to reduce the current stripping ratio in the initial period of development of deep deposits due to the temporary preservation of the sides and technology that provides a high rate of re-conservation.

This goal is achieved by the fact that the temporarily idle side forms at a steep angle close to the limit. At the level of the upper mark of the temporarily idle side, a horizontal platform is left, which, when the side is re-mothballed, is divided along the length into separate excavation blocks, including ready-made (blown up) and prepared for excavation volumes of rock mass. The blocks are mined by hydraulic excavators of the type “backhoe”, mounted on the roof of the worked benches, with the loading of the rock mass into vehicles, which are led to the surface at the exits located on the final side of the quarry. The height of the worked benches and the width of the run-in are taken based on the operating parameters of the excavator (depth and radius of digging). The working out of the ledges is carried out in layers from top to bottom. To protect the underlying working ledges from rockfall, at the base of the temporarily idle side along its entire length, a stone protection platform is provided, consisting of a platform for placing blasted rock mass falling from above, an embankment on which a hydraulic backhoe is located, and a transport platform. The blown up rock mass, falling during re-preservation of the side on a stone-protected platform, is loaded with a hydraulic excavator into vehicles and transported to the surface.

The method is illustrated by drawings.

In FIG. 1 reflects the division of the quarry on the queue indicating the sequence of work in Roman numerals (I, II, III). In FIG. Figure 2 presents a schematic plan for the development of a deep-seated field with the use of temporarily idle sides at the beginning of decommissioning. In FIG. Figure 3 shows the construction of a stone-protective platform that provides protection against rockfall of blasted rock mass falling from upper ledges during mining of edge ribbons.

The method is as follows.

Within the quarry field, as a rule, from the side of the hanging side (Fig. 1), a temporarily idle side (1) is formed, at a steep angle (2) close to the limit, a horizontal platform (3) is left at the level of the upper mark of the temporarily idle side, which, when re-preserving the sides, is divided along the length into separate blocks (4) (Fig. 2), including ready-blown (5) and prepared (6) volumes of rock mass for excavation, the blocks are mined using a hydraulic backhoe excavator (7 ) installed on the roof of the worked benches, with loading of the first rock mass to vehicles located at the same level, which are taken to the surface at the exits located on the final side of the quarry, the height of the worked benches and the width of the holes are taken based on the operating parameters of the excavators (depth and radius of digging), the benches are worked out in layers from the top down, on each ledge, the block located in the alignment of the congress, designed to ensure cargo transportation of the underlying ledge with the surface (8), is worked out ahead of schedule. After the construction of this congress, parallel mining of the underlying ledge begins (9), so that with a large width of the extraction blocks, more than one ledge can be in operation at the same time. In this order, the entire temporarily idle side is deconsolidated. To protect the rock from the ledges located below the temporarily idle side, a stone protection platform (10) is built along the entire length of its base, including a platform for placing blasted rock mass falling from above (11), an embankment (12), on which a hydraulic excavator of the “reverse” type is installed shovel ”(13), and a transport platform (14). The rock mass falling onto the stone-protected area is loaded onto vehicles (15) with a hydraulic excavator and transported to the surface. As mining operations decrease, the stone-protective site is moved to lower elevations (16), (17), providing the possibility of increasing the height of the temporarily idle side and the volume of conservation (18).

The specified set of essential features of the proposed method provides a significant reduction in current stripping ratios in the initial period of development of deep deposits, which ultimately provides highly efficient and safe development of such deposits without interruption in mining operations.

Information sources

1. Design of quarries / Khokhryakov B.C., Shelest A.G., Moltusov G.P. et al. - Moscow: Nedra, 1969 .-- 216 p.

2. Patent RU 2064582 C1 IPC E21C 41/26.

3. Linev V.P., Rubinstein S.B. Ensuring the safety of mining when using temporarily idle sides // Mountain Journal. - 2001. - No. 5. - S. 20-23.

Claims (1)

A method for open-pit mining of deep deposits using temporarily idle sides, characterized in that the temporarily idle side is formed at a steep angle close to the limiting level, at the level of the upper mark of the temporarily idle side, a horizontal platform is left, which, when the side is decommissioned, is divided into individual blocks, including ready-made (blown up) and prepared for excavation volumes of rock mass, mining of blocks is carried out by hydraulic excavators of the type “backhoe” mounted on the roof from working ledges, with loading the rock mass into vehicles at the same level, which are taken to the surface at the exits located on the final side of the quarry, the height of the worked ledges and the width of the entries are taken based on the operating parameters of excavators (depth and radius of digging), mining ledges are produced in layers from top to bottom, but when the excavation blocks of the worked ledge are moved by a sufficient amount and cargo transportation connection with the surface is provided, parallel mining of a single ledge, and so on, until the entire temporarily idle side is mothballed, to protect against rockfall of the ledges located below the temporarily idle side, a stone-protective platform is built at its base along the entire length, including a platform for accommodating the rock mass falling from above, an embankment, on which a hydraulic shovel type excavator is installed, and the transport area, the rock mass falling onto the stone protection platform, is loaded onto the vehicles with a hydraulic excavator and transported to the surface st, with decreasing mining operations stone-protective pad is moved to the lower mark, providing the possibility of increasing the height of temporarily non-working side and preservation volume.

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