RU2569100C1 - Method to stock granular wastes - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method to stock granular wastes into a section of a sludge pond, formed by barrier dams, a pit, with tier washing of wastes, to form a pool and a beach areas, a drainage device, comprising drains and water removal facilities arranged under the pit foot. And as barrier dams they use pit sides, the drainage is arranged in the form of a double-layer fill, at the same time the layer adjacent to the pit side, has larger size of fractions compared to the external one, and the water removal facility is represented by wells made in the pit side and connected to a water drainage canal.

EFFECT: increased reliability of the method for stocking of granular wastes.

4 cl, 1 dwg

Description

The invention relates to hydraulic engineering and can be applied when storing granular waste.

A structure for storing solid minerals during hydro production is known, including a reclamation map and a filter dam installed across the reclamation map, while it is equipped with a number of filter dams installed sequentially one after the other in the direction of flow, and the permeability of each subsequent dam decreases in the direction of travel ( AS USSR No. 1740672, E21C 41/32).

A disadvantage of the known solution is the low reliability of the structure, due to the fact that the high permeability of the primary dams determines a significant flow rate passing through each of them. As a result, the dam undergoes erosion. Its stability decreases, the likelihood of destruction under the influence of hydrostatic pressure, greater in magnitude, from the side of the upwash increases.

There is a method of storing granular waste in the section of the hydraulic dump and in the body of conservation over the section, characterized in that they first carry out a tiered reclamation of waste to the design level with the formation of a pond and beach zone in the section, the capacity of each tier of which is created by building dams, while in the upper part of the section on the beach of the longline, drainage is performed, which is located at a distance from and along the boundary dam of the longline and is equipped with a means of removing water from it, and the drainage in plan is placed under the sole, by at least one quarry planned for development during the execution of the boundary element of the layer, intended to create a conservation body over the section filled with waste, after which the first (lower) layer of the conservation body is washed, with the outer surface of which within the tier combine the outer side surface of the enclosing element tiers, then this surface is covered with a layer of reclamation (PI RF No. 2382847, E21C 41/32). In this case, drainage is performed at the base of the final tier of the alluvial waste in the section and / or the preceding tier of the tubular mattress type. In addition, the drainage is provided with transverse drains, and after washing the first tier of the conservation body, the subsequent tiers of the conservation body are washed, with the outer surface of each tier combining the outer side surface of the enclosing element of this tier. The washing of the first and subsequent tiers of the conservation body is carried out each time from a technological temporary prism, which is erected on the crest of the fencing element of the tier from soil material suitable for the subsequent implementation of the reclamation layer from it.

The disadvantage of this method is the lack of reliability. Fencing dams are formed by excavating dehydrated ash and slag from the beach area with the formation of a quarry and its subsequent filling. The removal of water is supposed to be carried out through a system including, in particular, drainage of a tubular-mattress type. The total resistance to the movement of the filtrate in this case is due to: water permeability of sediments of the beach area, drainage, hydraulic resistance of pipelines. At the same time, the water permeability of the beach area is relatively insignificant due to the fact that during its formation, ash and slag of various fractions form a fairly dense structure due to the natural layer-by-layer deposition of large fractions and then smaller ones.

Fencing dams have a significantly higher filtration coefficient than deposits of the beach area. This is due to the fact that their formation is carried out in bulk, without natural compaction. As a result, the structure of the enclosing dam is more porous and less dense. The space between large fractions is not filled with smaller ones.

Due to the fact that the enclosing dam creates less resistance to the movement of the filtrate than the drainage system, water will mainly move through the enclosing dam, gradually eroding it. The erosion of the enclosing dam leads to a loss of stability and reduces the reliability of the functioning of the hydraulic structure as a whole.

The technical problem to which the invention is directed is to increase the reliability of the method of storing granular waste.

The technical problem is solved in that in the known method of storing granular waste in a section of a hydraulic dump formed by enclosing dams, a quarry, with tiered reclamation of waste, the formation of a pond and beach areas, a drainage device including drains and a means of removing water located under the sole of the quarry, as the sidewalls of the quarry are used for quarrying, the drainage is carried out in the form of a two-layer dumping, while the layer adjacent to the side of the quarry has a larger fraction size than the outer one, and as a means of removing Water wells use wells made in the quarry and connected to the drainage channel.

In this case, the adjoining layer is formed from rocks of fractions of 50 ... 300 mm with a thickness of not less than 2000 mm, the outer one from rocks of fractions of 3 ... 5 mm, and a thickness of not less than 1000 mm, and wells are drilled within each tier.

In addition, flocculants in the amount of 0.01 ... 0.05 kg / t are fed into the waste before storage.

The use of open pit sides as enclosing dams has not been found in open sources.

In technical solutions, the use of layer-by-layer filling with components with different fractions is known (see the textbook “Building Streets and City Roads”, part 1 “Construction of the subgrade” / Edited by A.Ya. Tulaev, M., Stroyizdat, 1987, p. 301-310).

In the known technical solution, layer-by-layer filling provides a denser coating due to the fact that after each layer its compaction is ensured by tamping. Filling with a single layer initially to the entire required height does not allow creating sufficient normal stresses, which make it possible to obtain the density required from the technical conditions, and therefore the strength. Thus, layer-by-layer filling, in a known technical solution, provides an increase in coating strength.

In the proposed technical solution, the implementation of a two-layer filling of the drainage ensures the creation of zones with different hydraulic resistance. In conjunction with the choice of sizes of fractions, within the layers of dumping, an emergency breakthrough of the pulp is excluded.

The implementation of the layer adjacent to the side of the quarry, with a larger fraction of the fractions than the outer one, creates a lattice - a supporting structure that holds smaller fractions. A slope is created with an angle of inclination greater than what is characteristic of a layer of only a small fraction. This allows you to form a layer along the side of the quarry (in the transverse direction) with an inclination angle close to the angle of inclination of the side itself. At the same time, the fine fraction layer has a large hydraulic resistance, which eliminates the volley breakthrough of the pulp through it. Gradual colmatation, when filtering pulp through it, ensures the creation of a shielding layer. The shielding layer eliminates the ingress of pulp with a high content of fine granular fractions into the wells and drainage channels, their clogging and failure.

The use of wells made on board the quarry and connected to the drainage channel is known (see PI RF No. 2487997, E21C 41/16). In a known solution, drainage and degassing wells are carried out prior to commencement of operations directed from top to bottom in zones of increased fracturing and permeability outside the prepared mine working in close proximity to its profile and are used as means for removing gas-saturated brines.

In the proposed technical solution, wells are performed within each tier. This provides a continuous drainage of filtered water as the level of pulp in the dump increases. As the height of the tier increases, water is drained through a two-layer dumping. At the same time, part of the fine-grained fraction enters the well, gradually being deposited in it, reducing the conditional pass. When the pulp level reaches the upper boundary of the tier, a significant reduction in the conditional pass of the well is possible. The transition of the pulp level to the zone of the subsequent tier provides further drainage of filtered water through a new, previously unused well. Provides a continuous, stable drainage of filtered water.

The implementation of the adjoining layer from rocks of fractions of 50 ... 300 mm with a thickness of at least 2000 mm is not known.

It is also unknown the execution of the outer layer from rocks of fractions of 3 ... 5 mm, and a thickness of at least 1000 mm.

The supply of flocculants to the pulp is known (see AS USSR No. 893889 C02F 1/56). In a known solution, the supply of flocculants to the coal sludge is carried out by the release of suspended particles from the liquid. In the proposed solution, the feed is carried out into the pulp formed from the waste before discharge into the section of the hydraulic dump and does not contain useful components in the recoverable amount. In addition, the feed rate of 0.01 ... 0.05 kg / t was obtained experimentally and was not found in the known solutions.

Based on the foregoing, we can conclude that the inventive method of storing granular waste does not follow explicitly from the prior art, and therefore meets the patentability condition "inventive step".

In the inventive method of storing granular waste (in the section of the hydraulic dump), the technical result is achieved by the fact that the washing of the waste is carried out in tiers, with the formation of a pond and beach areas with pulp filling into the quarry space. In this case, the sides of the quarry, previously covered with a two-layer dumping, are used as enclosing dams. Dumping, carried out in a layer adjacent to the pit side, is carried out by rocks with a fraction size of 50 ... 300 mm. The thickness of the bed layer is at least 2000 mm. On top of the first layer, the second layer is poured with a thickness of at least 1000 mm and a fraction size of 3 ... 5 mm. To remove water that is filtered through a two-layer filling, wells are used that are made on board the quarry and connected to a drainage channel located under the sole of the quarry. Wells performed on board the quarry have exits to the side of the quarry, within each tier.

In addition, flocculants in the amount of 0.1 ... 0.5 kg / t are fed to the section in addition to the pulp with grain waste before storage.

The invention is illustrated by the diagram - FIG. 1, which presents a General scheme for implementing the method of storing granular waste.

The storage method is implemented as follows.

Before the storage of granular waste in the section of the hydraulic dump, which is used as quarry 1 (Fig. 1), the preparation of its sides 2 is carried out. The filling tiers are planned: 3, 4, 5. Water intake wells 6, 7 are drilled from the upper horizon of each tier, 8, 9 until they are connected to the drainage channel 10.

On board the quarry 2, the adjacent layer is filled with 11 fractions of rocks with dimensions of at least 50 mm and not more than 300 mm. The thickness of the layer is adjusted to 2000 mm.

Then, over the adjoining layer 11, the outer layer 12 is poured from rocks with a fraction size of 3 ... 5 mm and a thickness of at least 1000 mm.

After the preparation of the sides 2 is completed, the pulp of fine-grained and / or pulverulent solid waste, for example tailings, is stored. Filling is carried out from the opposite prepared side 2. In this case, a flocculant is preliminarily fed into the pulp in an amount of 0.01 ... 0.05 kg / t.

Waste in the form of pulp is washed in tiers: 13, 14, 15. Within each tier, pond 16, 17, 18 and beach 19, 20, 21 zones are formed. The capacity of each tier of alluvium 13, 14, 15 is fenced by the side of the quarry 2 and layers of dumping 11 and 12 on the one hand and the natural side on the other.

If necessary, the side opposite to the side of the quarry 2 can be prepared in a similar way.

When filling the quarry to the level of the first tier 13, a pond zone 16 and a beach zone 17 are formed. The pressure difference in the pond zone and the drainage channel 10 provides the filtrate in the direction of the side of the quarry 2. At the same time, granular waste is released from the filtrate when passing through the outer layer of dump 12. This is due to the size of the fraction 3 ... 5 mm, which creates resistance to the movement of suspended granular particles. Prior to layer 11 adjacent to the quarry pit, the bulk of suspended particles is retained in the outer layer 12. Next, the filtrate is collected by the intake well 6 and moves to the drainage channel 10. In the process of the filtrate moving through the intake well, the filtrate is refined and residual granular waste is separated from it. Gradually, the conditional passage of the water intake well decreases.

In the proposed technical solution, the implementation of a two-layer filling of the drainage 11 and 12 provides the creation of zones with different hydraulic resistance. Together with the choice of sizes of fractions, within each layer of dumping 11 and 12, emergency breakthrough of the pulp is excluded.

The implementation of the layer 11, adjacent to the side of the quarry 2, with a larger fraction size than the outer 12, creates a lattice - a supporting structure that holds smaller fractions. A slope is created with an inclination angle greater than that characteristic of a layer of only small fraction 12. This allows the formation of a layer 11 along the side of pit 2 (in the transverse direction) with an inclination angle close to the angle of inclination of the side 2. In this case, the layer of fine fractions 12 It has a large hydraulic resistance, which eliminates volley breakthrough through it of pulp. Gradual colmatation, when filtering the pulp through it, ensures the creation of a shielding layer within the layer formed of fine fractions 12. The shielding layer eliminates volley penetration of pulps with a high content of fine granular fractions into wells 6, 7, 8, 9 and the drainage channel 10, their clogging and failure.

The completion of wells 6–9 within each tier 3-5 individually provides continuous drainage of filtered water as the pulp level increases, the wash tiers 13, 14, 15. As the height of each tier increases, water is drained through a two-layer dumping. At the same time, part of the fine-grained fraction enters the well, respectively, 6, 7, 8, 9, gradually being deposited in it, reducing the conditional pass. When the pulp level reaches the upper boundary of the corresponding tier, a significant reduction in the conditional pass of the well is possible (6, 7, 8 or 9). The transition of the pulp level to the zone of the subsequent tier provides further drainage of filtered water through a new, previously unused well. Provides a continuous, stable drainage of filtered water.

The ratio of the size of the rock fractions of 50 ... 300 mm and the total thickness of the adjacent layer 11 of at least 2000 mm ensures its stability and eliminates spontaneous collapse that occurs with a smaller thickness of the adjacent layer 11.

The outer layer 12, formed from rocks of fractions 3 ... 5 mm with a thickness of not less than 1000 mm, provides sufficient permeability on the one hand and the required layer thickness, which forms the accumulation of a thin fraction of waste. With a smaller thickness of the layer until the completion of the alluvium of the tier, the wells are clogged to drain the water.

The sizes of the fractions and the thicknesses of layers 11 and 12 were determined empirically during the process of filling the Gaisky open pit with waste from enrichment production.

The supply of flocculants to the pulp in an amount of 0.01 provides it with high mobility and, as a result, a uniform distribution along the side of the quarry 2.

It was experimentally established that an increase in flocculants in the pulp of more than 0.01 g / t leads to an increase in its mobility, sufficient for the formation of beach zones 19-20 and intense water output. This trend persists until the content of flocculants in the pulp is 0.05 g / t. With a further increase in the content, the mobility practically does not change. In this regard, to increase the content of flocculants more than 0.05 g / t is impractical, as this leads to an increase in costs without the manifestation of additional effects.

When conducting laboratory tests of the invention in the conditions of the Gaisky quarry of JSC "Gaisky GOK", in paragraph 4, the following was established.

When conducting 48 series of experiments with different flocculant contents in the pulp from 0.005 g / t to 0.08 g / t.

It was found that the best indicators: a spreading angle of 3-5 degrees and a spreading time are provided when the flocculant content is in the amount of 0.01 ... 0.05 kg / t.

Claims (4)

1. A method of storing granular waste in a section of a hydraulic dump formed by enclosing dams, a quarry, with a tiered alluvial waste, with the formation of a pond and beach areas, a drainage device including drains and water removal means located under the sole of the quarry, characterized in that as enclosing the sides of the quarry are used in the dams, the drainage is carried out in the form of a two-layer filling, while the layer adjacent to the side of the quarry has a larger fraction size than the outer one, and is used as a means of removing water with Vazhiny formed in the pit walls and connected to the drainage channel. 2. The method according to p. 1, characterized in that the adjacent layer is formed from rocks of fractions of 50 ... 300 mm with a thickness of 2000 mm, the outer one from rocks of fractions of 3 ... 5 mm and a thickness of at least 1000 mm. 3. The method according to p. 1, characterized in that the wells are performed within each tier. 4. The method according to p. 1, characterized in that the waste prior to storage in the section serves flocculants in an amount of 0.01 ... 0.05 kg / t

Images