RU2629187C1 - Method for dredge work of placer deposits - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method involves stripping in the contours of industrial reserves, reducing the thickness of productive deposits by cutting them to a depth, sufficient to mine out the remaining part with the dredge, moving the cut off productive deposits into the trench and dredging the prepared stocks. In this case, the trench is formed on unproductive areas located along the travel of the dredge, and the cross-section area of the cut off rocks of productive deposits in the trench is established from the ratio of the volume of these deposits and the length of the unproductive area. And the trench is formed with a depth, which ensures placement of productive deposits with the maximum permissible thickness for the dredge with the minimum allowable width of the face.

EFFECT: increase the productivity of stripping and mining equipment by optimizing the parameters of the dredge, including by controlling the size of the sand bulks in the trench.

2 dwg

Description

The invention relates to mining operations and can be used when dredging placers or fields with deposits with a productive layer capacity exceeding the maximum permissible dredging face height.

The thickness of the reservoir at alluvial deposits varies over a fairly wide range. When choosing a dredge for the development of a specific field, as a rule, they are guided by the average thickness of the reservoir. Moreover, throughout the placer there are areas with a capacity exceeding the dredging capacity (greater than the sum of the maximum digging depth and the maximum freeboard). In many cases, such areas are underdeveloped in depth and part of the mineral remains in the bowels.

Currently, deep dredging dredges with sand excavation depths of 30 to 50 m are used to develop deep placers. However, the use of such unique dredges in medium-depth placers with rare areas with high productive sediment thicknesses is not economically justified.

Known methods of excavation of sand from near-sedimentary sediments and rafting raft located below the depth of digging [and.with. No. 209340 - Bull. Inv., 1968, No. 5; A.S. No. 275911 - Bull. invent., 1970, No. 23; A.S. No. 283141 - Bull. invent., 1970, No. 31; A.S. No. 292714 - Bull. inv., 1971, No. 5]. However, these methods are suitable for excavating small volumes of sand and the devices used have a low productivity. In addition, their use entails significant downtime and will lead to a decrease in mining.

A known method of dragee mining of placer deposits [and.with. 1802575, according to IPC Е21С 41/32 (A.V. Gurichev, V.A. Kudryashev and B.L. Talgamer) dated 07.26.90], according to which, in order to reduce the cost of developing powerful productive deposits by ensuring the possibility of their extraction by dredges of serial production, carry out a trench along the border of productive sediments beyond the contour of industrial stocks, reduce the power of productive sediments by cutting them to a depth sufficient for mining the remaining parts by dredges and move the rocks into the trench, after which dredging is carried out in industrial circuits, and then after omyshlennym circuit.

The signs of the prototype, which coincide with the existing features of the proposed method, are the opening in the contours of industrial stocks, reducing the power of productive deposits by cutting them to a depth sufficient to mine the remaining part of the dredge, moving the cut productive deposits into the trench and dredging the prepared reserves.

A comparative analysis of the proposed technical solution with the prototype shows that the main disadvantage of the latter is a significant expansion of the dredging course in areas with a large capacity of the reservoir. On placers with peat, the expansion of the dragee passage leads either to overexcavation, or to a significant lengthening of the distance of transportation of waste rock to dumps placed on the sides of the dragee cut. Due to the fact that the capacity of peat on newly put into operation alluvial deposits is growing and in many cases draglines are used for overburden operations, the expansion of the dredge course leads not only to a significant increase in the volume of over-excavation, but also to a noticeable increase in basement areas. The latter in many cases is impossible due to the lack of conditions for the removal of surface water from the mining area or the steep slopes of the valley, where dumping is not allowed.

In addition, the expansion of the dragee course in many cases leads to a decrease in the dredge productivity due to an increase in the face width or the need for dredging by adjacent faces.

The invention is aimed at increasing the efficiency of dredged mining of placers by reducing the cost of re-excavation of waste rock, increasing dredge productivity and reducing the negative impact on water resources.

The technical result consists in increasing the productivity of overburden and mining equipment by optimizing the transverse parameters of the dredging course (face), including within the trench.

The technical result is achieved by the fact that in the method of developing alluvial deposits described in the claims, which includes opening industrial contours in the contours, reducing the capacity of productive deposits by cutting them to a depth sufficient to mine the remaining part with dredge, moving the cut productive deposits into the trench and dredging prepared reserves, according to the invention, a trench is formed in unproductive areas located along the course of the dredge, while the cross-sectional area Ia cut productive deposits in the trench is set volume ratio of these deposits and the unproductive portion length and depth of the trench is formed, ensuring occupancy productive deposits at the maximum permissible power for dredge at the minimum allowable width.

Differences from the prototype prove the novelty of the invention.

In well-known development methods, when driving dredges through unproductive areas, either alloy channels specially constructed by excavators or bulldozers with a depth below the water level are greater than the minimum permissible for the dredge, or water dams with a rise in water level are constructed, or the alloy channel is formed by the dredge itself with fine-grained dredging .

All of the above methods of driving dredges are quite laborious and require significant additional costs, as well as the construction of a trench along the course of the dredge beyond the contour of the stock to store the upper part of the reservoir, which cannot be worked out by the dredge due to the restriction of the height of the face (see prototype).

The proposed technical solution proposes to combine the sinking of the alloy channel with the construction of the trench by forming the latter along the dredge in the unproductive section of the dredging ground. At the same time, it is proposed to establish the parameters of the trench based on the volume of transported sand from the upper part of the reservoir, the length of the unproductive section and the conditions for ensuring the maximum productivity of overburden and mining (dredge) equipment.

Provided that overburden is placed on the sides of the dredged cut to increase the productivity of mining equipment, the width of the trench should be minimal. At the same time, the width of the trench along the bottom should not be less than the minimum permissible width of the dredged bottom based on the technical characteristics of a particular dredge.

To ensure maximum dredge productivity for a certain cross-sectional area of prepared reserves, the best ratio of the width and thickness of the sand pile should be established. It is proposed to calculate this ratio based on the optimal dredging maneuvering angle. For a specific cross-sectional area of the productive formation S and the desired ratio of the average width and thickness of the pile of sands B / H = Y, we have

Using the proposed V.G. Peshkov [Leshkov V.G. Development of alluvial deposits: Textbook for technical schools. - M .: Nedra, 1985 .-- 568 p. S.462-463] the dependence of the optimal maneuvering angle on the dredging parameters after the necessary transformations, we establish:

where V is the speed of the scoop chain, m / s; h - the value of the layer-by-layer lowering of the frame, m; t ₁ , t ₂ - respectively, the duration of the stepping and downtime of the dredge in the corners of the face when lowering the frame, min; R is the dredging radius of the dredge on the middle horizon of a pile of sand, m.

Hence, for a certain value of S, taking into account the technical characteristics of the dredge and the adopted dredging parameters, the optimal V / H ratio is established.

As a result of the analysis of the dependence of the daily dredge productivity on the B / H = Y ratio for various mining conditions and dredging parameters, it was found that the maximum productivity will occur at Y values close to the minimum. From this it follows that the power of the sand poured into the trench should be maximum.

Given the fact that most alluvial deposits are located in valleys with a high level of groundwater, overburden operations are usually associated with water reduction in order to drain peat (overburden). In many cases, the water decrease is 10-15 m. In such conditions, to drive the dredge with alloy through unproductive sections, it is necessary to significantly raise the water level in the technological reservoir of the dredge to plant it in the alloy channel, and subsequently re-pump the water from the dragee section when opening the reserves located for the unproductive area. Thus, in the process of driving the dredge, it is first necessary to raise the water level, and after the drive it is pumped out and dumped with additional costs for its clarification.

The proposed technical solution eliminates significant changes in water level, since the depth of the trench in the unproductive area is taken as maximum. Due to this, fresh water withdrawal and wastewater discharge are not changed and the impact of mining on water resources is reduced.

The invention is illustrated by drawings, where

- in FIG. 1 shows a longitudinal section of a dredging range along the course of a dredge with a trench and a bulk of sand in it according to the claims,

where 1 is the trench;

2 - bulk sand in the trench;

3 - reservoir;

4 - dredge;

5 - contour of industrial stocks;

6 - peat (overburden);

7 - placer raft;

- in FIG. Figure 2 presents an algorithm for substantiating the parameters of a trench for storing a pile of sand with optimal transverse parameters into it.

The method described in the claims is as follows. Along the course of the dredge, a trench 1 with a depth of H _tr is formed in an unproductive section of length L with sufficient lead. In the trench, 2 sands transported from the areas of the dredge landfill having the thickness of the productive layer 3 are greater than the maximum height of the dredged face H _n > (N _h + h _nb ) are stored in bulk. _Mp trench depth H is set based on the conditions for ensuring all the storage volume transported sands. After dredging 4 whole productive deposits in the contours of industrial reserves 5, dredging of bulk sand into the trench is carried out.

The parameters of the trench for storing sand are determined taking into account the volume of the latter and the length of the unproductive area of the placer. Based on the ratio of these values, the cross-sectional area of the bulk of the sand in the trench is established. After that, taking into account the cross-sectional area and the minimum width of the dredge bottom, the maximum possible thickness of the pile of sand is calculated and, by comparing it with the maximum dredge bottom height, the bottom width either increases, or a decision is made either to reduce the length of the trench or to raise the water level in the drage section ( see Fig. 2).

With a peat thickness of 6 N _t > 6-8 m and the possibility of water reduction in the overburden excavation, a trench is formed with a maximum depth, up to the placer raft 7. The length of the trench is assumed to be less than the length of the unproductive section L _tr <L.

In order to reduce the negative impact on water resources, it is recommended to leave the water level in the technological reservoir 8 during mining of a pile of sand in a trench unchanged.

Claims (2)

A method of dredged mining of alluvial deposits, including opening industrial contours in the contours, reducing the capacity of productive deposits by cutting them to a depth sufficient to mine the remaining part with dredge, moving the cut productive deposits into the trench and dredging the prepared reserves, characterized in that the trench is formed in unproductive areas located along the course of the dredge, and the cross-sectional area of the cut rocks of productive sediments in the trench is established from the ratio of volume and the length of these deposits and the unproductive portion, the depth of the trench is formed, ensuring occupancy productive deposits at the maximum permissible power for dredge at the minimum allowable width of the face.

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