KR100879917B1 - Tailing stability method of river at mine district - Google Patents

Abstract

A tailing/waster rock stabilization method of river at closed mine region is provided to delay stream of the river through the flux reduction facility, thus preventing the corrosion of cover soil. A tailing/waster rock stabilization method of river at closed mine region comprises a step of forming a tailing/waster rock solidification layer(20) by supplying calcium hydroxide and water to a tailing/waster rock layer(T) between a tailing dam(D) and a concrete dam(10), a step of constructing a gravel layer(30) on the top of the tailing/waster rock layer and the tailing dam, a step of constructing a cover layer(40) lower than the concrete dam, and a step of constructing a flux reduction facility(50).

Description

Tailing stability method of river at mine district

The present invention relates to a method for stabilizing tailings and light waste-rock, and in particular, to prevent the outflow and leaching of tailings and mine waste-rock accumulated in the streams around the waste mines to remove soil and water pollution sources in the vicinity. In addition, the present invention relates to the stabilization of tailings and mineral wastes stored in the streams of the closed mine area, which can preserve the river ecosystem and prevent the groundwater contamination, which is the secondary source of pollution, to ensure safety measures and pleasant environment for the surrounding areas.

The tailings and the waste-rock are the residues from the mines, which are the mineral residues left after grinding ore to select the necessary components.

In general, tailings and waste-rock are spilled by heavy rainfall in summer, or heavy metals are eluted to contaminate nearby rivers. In winter, tailings particles are scattered, contaminating settlements and farmland around mines. In addition, the soil around the mine will continue to receive pollutants, containing dozens or hundreds of times more heavy metals than uncontaminated soil. In particular, if the tailings and waste-rocks of metal mines contain sulfides, they react with dissolved oxygen in water to produce strong acidic acid water to elute heavy metals, which are leached into the leachate and contaminate the surrounding soil and surface or ground water. Let's do it. Therefore, the tailings and the waste-rock are the most desirable water pollution prevention methods to fundamentally block the contact with water.

Typically, the treatment method of tailings and light waste-rock is a landfill method, a solidification / insolubilization method, a landfill movement and a neutralization / stabilization / solidification method.

The reclamation method is a method of constructing and reclaiming a tailings dam, which is a mine waste storage facility such as a retaining wall or soil embankment, in the vicinity of the mine, and, if necessary, adds a variety of water repellent or cover, or manages the waste by planting. However, in the landfill method, there is always a problem that the tailings and the waste-rock are moved to soil or river water and groundwater during the rainy season, which threatens the ecosystem around the mine area.

The solidification / insolubilization method is a method of chemically treating the tailings and the light waste-rock to demigrate the elutable harmful components present in the waste-rock, and stabilizes the harmful components and then builds the tailings storage facility as in the landfilling method. It is one of the solidification methods. However, the solidification / insolubilization method has a disadvantage in that a lot of construction costs.

The landfill movement plan is to either mine the mine waste itself separately in a nearby area or move it to a specific existing landfill, which is possible for small-scale waste. Therefore, there is a limit to the application in the case of treating a large amount of waste, and further challenges remain due to the site use.

Neutralization / stabilization / solidification method is a method of blocking the outflow of sulfide components in principle by filling the small pores by using the acid-chemically modified acid neutralization and heavy metal treatment agent in the tailings and the light waste-rock layer. Even if the tailings and waste-rocks buried in the tailings field are in contact with the groundwater, they can already form a film on the surface with acid neutralization and heavy metal treatment agents to prevent the acid and heavy metals from leaking, and there is no need for follow-up processes. In addition, there is an advantage that the construction cost is low, but there is a problem that can not guarantee the continuous stabilization efficiency of the treatment agent to achieve the neutralization / stabilization.

Conventional tailings and waste-rock treatment techniques as described above are only a temporary measure to minimize the reaction rate and are stored in a fixed place until better inertness and recovery techniques are developed. There is a need for an improved storage treatment technology that can minimize the environmental damage by deactivating the tailings and the waste-rock in the long term.

Currently, the method of treating mine waste, which is being performed in Korea, is mainly a landfill method by installing a storage structure among the above methods. In more detail, the tailings and tailings are deposited in streams in the surrounding area adjacent to the abandoned mines, and the tailings dams are constructed across the streams without moving the tailings and tailings generated from the abandoned mines farther. It is using a method to prevent the flow in the direction. However, this reclamation method merely stacks tailings and tailings rocks, and there is a problem that tailings and tailings rocks easily flow over the tailings dam during the rainfall and flow into the downstream region to contaminate the soil or water quality in the downstream region. In addition, if the tailings dam is lost, there is a problem in that the tailings and the waste-rock are lost to the lost place, and the tailings and the waste-rock layer are in direct contact with the river water and the heavy metal is eluted.

The present invention has been made to solve the above problems of the prior art, to build a concrete dam on the downstream side of the tailings dam installed in order to prevent the leakage of tailings and tailings accumulated in the rivers around the waste mines, The present invention provides a method for stabilizing tailings and mineral waste deposited in rivers in the closed mine area, which prevents the leaching of heavy metals by forming a cover layer on the upper side of the tailings and mineral waste. There is a purpose.

In order to solve the above problems, the method of stabilizing tailings and tailings in a river in a waste mine area according to the present invention provides a tailings dam in a stream in a waste mine area and tailings upstream of the stream based on the tailings dam. And a method for stabilizing tailings and tailings stones in which tailings are stacked, wherein a concrete dam is constructed higher than the tailings dam and the tailings / tailings layer on the downstream side of the tailings dam. Slaked lime and water are supplied to the tailings / mineralized rock layer deposited between the tailings dam and the concrete dam to form a solidified tailings / mineralized rock solidifying layer; Constructing a gravel layer with a height of 20 to 30 cm on the upper surface of the tailings / mineral rock layer and the upper surface of the tailings dam deposited on the upstream side of the tailings dam; Forming a cover layer on the upper surface of the tailings / light waste stone solidifying layer and the gravel layer at a height of 80 to 100 cm lower than the height of the concrete dam; It comprises the step of constructing a flow rate reduction facility on the stream upstream of the gravel layer and cover layer.

In addition, the method of stabilizing tailings and tailings in the streams of the abandoned mine area according to the present invention includes installing tailings dams in streams in which a plurality of tributaries join, and tailings and tailings rocks upstream of the river based on the tailings dams. And a method for stabilizing tailings and tailings rocks, wherein the concrete dams are constructed higher than tailings dams and tailings / tailings beds in the downstream side of the tailings dams; Installing a U-shaped opening on the side of the tailings / mineralized rock layer so that a plurality of tributary flows joining the streams can flow through; Slaked lime and water are supplied to the tailings / mineral waste layer having a constant width in contact with the U-shaped clearing and the tailings / mineral waste layer having a constant width in contact with the concrete dam to form a solidified tailings / mineralized solidification layer; Constructing a gravel layer at a height of 20 to 30 cm on the upper surface of the tailings / light waste rock layer and the upper surface of the tailings / light waste stone solidifying layer; And a step of constructing a cover layer on the upper surface of the tailings / mineral rock layer and the tailings / mineral rock solidification layer and the upper surface of the tailing dam to a height of 80 to 100 cm lower than the height of the concrete dam and U-shaped open space.

According to the stabilization method of the tailings and the mineral waste deposited in the river of the waste mine area according to the present invention configured as described above, because the river water is not in contact with the tailings / mineral waste layer by the gravel layer and cover soil layer, by the river water flowing through the river There is an advantage that can prevent the heavy metal inherent in the tailings / light waste-rock to flow out.

In addition, since the tailings / mineral waste layer is solidified and a gravel layer and a covering layer are formed thereon, there is an advantage of preventing secondary environmental pollution caused by the tailings lost by preventing the loss of the tailings.

In addition, there is an advantage to prevent the cover layer erosion by slowing the flow of river water by installing a flow rate reduction facility.

Hereinafter, with reference to the accompanying drawings an embodiment of the method of stabilizing the tailings and light waste-rock deposited in the river of the waste mine area according to the present invention.

1 is a perspective view showing an embodiment constructed by the method of stabilization of tailings and mineral waste deposited in the stream of the waste mine area according to the present invention, Figure 2 is stacked in the river of the waste mine area shown in Figure 1 It is sectional drawing of the stabilization method of a tailings and a light waste-rock.

In addition, Figure 3 is a perspective view showing another embodiment of the tailings and the method of stabilizing the tailings in the waste mine area in accordance with the present invention, Figure 4 is a tailings accumulated in the river in the waste mine area shown in Figure 3 And cross-sectional view of a stabilization method of a light waste-rock.

In the stabilization method of tailings and tailings accumulated in the stream of the abandoned mine area according to the present invention, the tailings dam (D) is installed in the stream of the neighborhood of the abandoned mine, and the tailings / light accumulated on the upstream side of the stream based on the tailings dam. As to stabilize the waste-rock layer (T), the construction of the concrete dam 10 downstream of the tailings dam (D), the tailings / light waste-rock layer deposited between the tailings dam (D) and the concrete dam (10) A tailings / mineralized rock solidification layer 20 is formed at (T), and a predetermined height is formed on the upper surface of the tailings / mineralized rock layer T and the upper surface of the tailings dam D stacked upstream of the tailings dam D. The construction of the gravel layer, and the construction of the cover layer 40 on the upper surface of the tailings / light waste stone solidified layer 20 and the gravel layer 30 lower than the height of the concrete dam 10, and the gravel layer 30 and It consists of constructing the flow rate reduction facility 50 in the stream upstream end of the cover layer (40).

The concrete dam 10 is to be installed on the downstream side of the tailings dam (D) installed to block the river, and is constructed higher than the tailings dam (D) and tailings / tailings layer (T). Of course, if the height of the tailings dam D is higher than the height of the constructed concrete dam 10 by constructing the height of the concrete dam 10 a little lower, the tailings dam D is completely removed or the upper part of the tailings dam D is removed. By demolishing it is also possible to lower the height of the tailings dam (D) than the concrete dam (10).

In addition, an incision 10a is formed at the center of the upper surface of the concrete dam 10 so that the river water flowing on the cover layer 40 flows downstream of the river.

The tailings / mineral waste solidifying layer 20 is solidified by supplying slaked lime and water to the tailings / mineral waste layer (T) stacked between the tailings dam (D) and the concrete dam (10). The tailings / mineral rock layer (T) is the one that has been deposited in front of the tailings dam (D) between the tailings dam (D) and the concrete dam (10). By solidifying this, the strength and hardness are strengthened. As a result, the tailings / mineral rock layer (T) is lost due to the runoff during heavy rains such as the rainy season in summer, to prevent environmental pollution in the downstream region.

On the other hand, the slaked lime and water added to solidify the tailings / light waste-rock layer is 5 to 7 parts by weight of the slaked lime, 13 to 15 parts by weight of water with respect to 100 parts by weight of tailings / mineral waste.

The gravel layer 30 is to be installed on the upper surface of the tailings / light waste stone layer (T) and the tailings dam (D) with a thickness of 20 ~ 30cm, deposited on the lower side by the river water flowing through the upper surface of the cover layer (40) Heavy metals in the tailings / mineral rock layer (T) are intended to prevent the elution and increase in the inflow into the river water by capillary action.

The cover layer 40 is used on the bottom surface of the tailings / mineralized rock solidification layer 20 and the gravel layer 30 to be used as a river bottom surface so that the construction thickness is about 80 ~ 100cm. At this time, the upper surface of the cover layer 40 is preferably lower than the height of the concrete dam 10, in more detail, the same height as the bottom of the cutout (10a) formed in the concrete dam (10). This is because the river water flowing upward of the cover layer 40 can flow smoothly to the downstream side of the river through the cutout portion 10a of the concrete dam 10.

The flow rate reduction facility 50 is a concrete block 51 installed at the same height as the upper surface of the cover layer 40 at the ends of the gravel layer 30 and the cover layer 40, and the concrete block 51 of the river It consists of the reduction gear layer 52 provided in an upstream.

The concrete block 51 is composed of a vertical portion (51a) vertically installed on the bottom surface of the river and a horizontal portion (51b) extending from the end of the vertical portion (51a), the vertical portion (51a) It is preferable that the height of the upper surface is the same as the upper surface of the covering layer 40. Only then is the flow rate of the stream water flowing through the stream decelerated firstly by hitting the fresh water stream flowing through the decelerating layer 52 and then hitting the vertical portion 51a of the concrete block 51 to reduce the secondary layer 40. ), The erosion of the cover layer 40 can be prevented. In addition, in view of the decrease in the flow rate of the river water, the decelerating gravel layer 52 may be composed of gravel having a particle size larger than that of the gravel layer 30 constructed on the top surface of the tailings / mineral rock layer T. The particle size may be about 0.5 m2.

On the other hand, the scour prevention gravel layer 70 is formed on the upper surface of the cover layer 40 adjacent to the flow rate reduction facility 50. This is to prevent the cover layer 40 from being eroded by the river water flowing over the concrete block 51 of the flow rate prevention facility 50 to the cover layer.

In the above description, an embodiment of a method of stabilizing tailings and mineral waste deposited in a river in a waste mine area according to the present invention has been described, and another embodiment will be described below.

The stabilization method of the tailings and the mineral waste deposited in the rivers of the closed mine area according to the present invention configured as described above can also be applied to a stream in which a plurality of tributaries join, in which case the concrete dam 10 and the U-shaped clearing ( 60), the tailings / mineralized rock solidification layer 20, and the cover layer 40.

The concrete dam 10 is constructed higher than the tailings dam D and the tailings / mineral rock layer T on the downstream side of the tailings dam D, and thus description thereof will be omitted here. .

The U-shaped clearing 60 is installed on the side of the tailings / mineral waste layer T so that a plurality of tributary flows joining the stream can flow. The U-shaped opening 60 preferably forms a U-shaped cutout 61 so that the water of the tributary flows in a portion in contact with the tributary.

The tailings / mineralized rock solidification layer 20 has a constant width of tailings / mineralized rock layer T in contact with the U-shaped open space 60 and a constant width of tailings / mineralized rock layer in contact with the concrete dam 10 (T). ) Is solidified by supplying slaked lime and water. Along the side of the tailings / light waste stone solidification layer 20 is a U-shaped clearing 60 is installed.

The cover layer 40 is constructed with a thickness of 80 ~ 100cm on the upper surface of the tailings / light waste rock layer (T) and the tailings / light waste stone solidification layer 20 and the top surface of the tailings dam (D), the concrete dam (10) And lower than the height of the U-shaped opening (60).

Here, the tailings / light waste stone solidifying layer 20 and the cover layer 40 is the same as the embodiment and the configuration thereof will be omitted here.

1 is a perspective view showing an embodiment by the method of stabilizing the tailings and light waste-rock deposited in the rivers of the abandoned mine area according to the present invention.

FIG. 2 is a cross-sectional view of an embodiment by a method of stabilizing tailings and mineral waste deposited in a river in the waste mine area shown in FIG. 1; FIG.

Figure 3 is a perspective view showing another embodiment according to the stabilization method of tailings and mineral waste deposited in the rivers of the abandoned mine area according to the present invention.

4 is a cross-sectional view of another embodiment by a method of stabilizing tailings and mineral waste deposited in the rivers of the abandoned mine region shown in FIG.

<Explanation of symbols on main parts of the drawings>

10: concrete dam 20: tailings / mineralized solid layer

30: gravel layer 40: cover layer

50: flow rate reducing facility 51: moncrete block

52: decelerator bed 60: U-shaped clearing

70: scour prevention gravel layer D: tailings dam

T: tailings / mineral rock layer

Claims (8)

The tailings dam (D) is installed in the stream of the closed mine area, and the tailings and tailings are piled upstream of the stream based on the tailings dam (D), and the tailings dam (D) is downstream of the tailings dam (D). And in the tailings and light waste-rock stabilization method that is higher than the tailings / light waste-rock layer (T), the concrete dam 10 with a cutout (10a) is provided in the center of the upper surface so that the river water flows to the downstream side of the river, Forming slag tailings / mineralized solidification layer (20) by supplying slaked lime and water to the tailings / mineralized rock layer (T) deposited between the tailings dam (D) and the concrete dam (10); Constructing a gravel layer (30) at a predetermined height on the upper surface of the tailings / mineralized rock layer (T) and the upper surface of the tailings dam (D) deposited on an upstream side of the tailings dam (D); Constructing a cover layer 40 on the upper surface of the tailings / light waste stone solidifying layer 20 and the gravel layer 30 lower than the height of the concrete dam 10; Method of stabilizing tailings and mineral waste deposited in the river in the closed mine area, characterized in that comprising the step of constructing a flow rate reduction facility (50) at the stream upstream end of the gravel layer (30) and the cover layer (40). A tailings dam (D) is installed in a stream where a plurality of tributaries join, and tailings and tailings are placed upstream of the stream based on the tailings dam (D), and the tailings dam (D) is located downstream of the tailings dam (D). D) and in the tailings and light waste-rock stabilization method of constructing the concrete dam 10 higher than the tailings / light waste-rock layer (T), Installing a U-shaped clearing (60) on the side of the tailings / mineralized rock layer (T) so that a plurality of tributary flows joining the streams can flow through; The tailings and the light-mineralized rock layer (T) having a constant width in contact with the U-shaped clearing 60 and the tailings and the light-mineralized rock layer (T) having a constant width in contact with the concrete dam 10 are solidified by supplying slaked lime and water. / Forming a light waste-rock solidification layer 20; The cover layer 40 is lower than the height of the concrete dam 10 and the U-shaped clearing 60 on the upper surface of the tailings / light waste rock layer (T) and the tailings / light waste stone solidifying layer 20 and the upper surface of the tailing dam (D). And stabilizing the tailings and the waste-rock in the rivers of the closed mine area, characterized in that it comprises a) construction. delete delete The method according to claim 1, In the step of constructing the flow rate reduction facility 50, the concrete block 51 is installed at the ends of the gravel layer 30 and the cover layer 40, Stabilization method of tailings and light waste-rock accumulated in the stream of the closed mine area, characterized in that for installing the flow rate reduction facility 50 by installing the decelerating gravel layer 52 on the upstream side of the stream on the basis of the concrete block (51). . The method according to claim 5, Method of stabilizing the tailings and light waste stone deposited in the river in the abandoned mine area, characterized in that it comprises the step of forming a scour prevention gravel layer 70 on the upper surface of the cover layer 40 adjacent to the flow rate reduction facility (50). The method according to claim 1, In the step of constructing the gravel layer 30, the construction thickness of the gravel layer 30, the stabilization method of tailings and mineral waste deposited in the rivers of the closed mine area, characterized in that 20 ~ 30cm. The method according to claim 2 or 7, In the step of constructing the cover layer 40, the construction thickness of the cover layer 40 is 80cm ~ 100cm, characterized in that the stabilization method of tailings and mineral waste deposited in the river in the closed mine area.

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