KR20100013474A - Spiral gravity separator - Google Patents

Abstract

PURPOSE: A spiral gravity separator is provided to efficiently and economically separate each component from sand in a process for separating useful minerals included in sand with an air spraying device spraying the air to processing liquid. CONSTITUTION: A spiral gravity separator(100) comprises the following: an inlet(11) arranged according to a vertical direction and receiving processing liquid; a waterway part arranged on a spiral shape to flow the processing liquid to a lower direction; a spiral body(10) with an outlet discharging the processing liquid; a partition member(20) arranged on the outlet; and a middle outlet formed on the waterway part penetrating the spiral body and arranged according to a width direction of the spiral body.

Description

Spiral gravity separator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spiral specific gravity sorting apparatus for recovering useful minerals contained in sand by using a difference in specific gravity, and particularly for recovering useful minerals from sea sand.

Useful minerals such as ilmenite, rutile, zircon, silimanite, and monazite are used as essential raw materials in various industries. That is, titanium iron is used as a welding rod, a special magnetic material, or a sunscreen pigment, and zircon is used in ceramics, high-quality bearings, and ball mills.

However, in the case of the above-mentioned minerals, almost all of them depend on imports in Korea, and in recent years, the price of raw minerals soared in the world, and the price has been increasing significantly. For example, rutile and silimite are priced at $ 200 / tonne and zircon at $ 900 / tonne. Accordingly, the necessity of developing such rare raw minerals in Korea without relying solely on imports has been raised, but has not achieved effective results.

On the other hand, it is investigated that the sand on the coast of Korea, that is, the sea sand, contains useful minerals such as titanium iron and monazite. In other words, 1.5% of the sea sand consists of the above useful minerals. According to the 2006 Ministry of Construction data, 23 million tons of seawater is reported to be developed and used as construction materials, and 23 million tons contain about 500,000 tons of useful minerals, and the economic value of these useful minerals is nearly 500 billion. will be. Therefore, the development of a technology for recovering useful minerals from the sea.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a spiral specific gravity sorting apparatus which is used to separate the sea sand according to specific gravity as a first process for separating useful minerals from sea sand.

The spiral specific gravity screening device according to the present invention for achieving the above object is to separate the useful minerals from the treatment liquid containing the useful minerals and sand and water mixed with components having different specific gravity, Longitudinally disposed along the up and down direction, an inlet portion into which the treatment liquid flows in, a water passage portion spirally arranged so that the treatment liquid introduced into the inlet portion rotates downward, and an outlet portion through which the treatment liquid flows out are provided. And a partition member disposed at the outlet portion so that the treatment liquid flowing out to the outlet portion of the spiral body is separated and discharged into a plurality of forks. The spiral bone is disposed on the outside along the width direction of the channel portion so as to be removed in the portion. The intermediate outlet port penetrating the is characterized in that is formed in the channel unit.

According to the present invention, it is preferable to further include a blocking member disposed along the width direction of the water channel at the rear end of the intermediate discharge port in the advancing direction of the processing liquid to block the progress of the processing liquid.

In addition, according to the present invention, the intermediate outlet is preferably disposed between the intermediate point and the inlet portion of the entire path of the waterway portion.

Further, according to the present invention, the treatment liquid is disposed at the rear end of the intermediate discharge port in the advancing direction of the treatment liquid, and the treatment liquid is disposed in a direction intersecting with the traveling direction of the treatment liquid so that the treatment liquid is widely expanded and disposed along the width direction of the channel portion. It is preferable to further provide an air injection device for injecting air toward the liquid.

Spiral specific gravity screening apparatus according to the present invention is used in the specific gravity screening process of the process for separating useful minerals contained in the sea sand, it is possible to very efficiently and economically separate relatively large components and small components from the sea sand There is an advantage.

First, a brief description will be given of the entire process of separating useful rare minerals from seawater. 1 is a flowchart illustrating a schematic process for extracting useful minerals from seawater.

Referring to FIG. 1, first, the seaweeds are collected, and then screened according to the particle size. Specifically, only particles having a diameter of about 2 mm or less are separated by screening using a sieve net.

Then, the first specific gravity screening process is performed using the spiral specific gravity screening apparatus according to the present invention. The spiral specific gravity sorting apparatus according to the present invention is used to separate the maritime by specific gravity in the process of descending the maritime through the spiral channel, which will be described later.

When the primary specific gravity screening process is completed, the secondary specific gravity screening process is performed on the heavy minerals using a so-called shaking table. The shaking table generates vibrations while constantly reciprocating the inclined table, thereby separating the seawater into relative heavy and hard minerals.

The heavy minerals separated again by the second specific gravity screening are subjected to magnetic screening using magnetism after dehydration and drying. In magnetic screening, sea sand is separated into weak magnetic particles and non-magnetic particles, and finally, the final useful mineral is separated by electrostatic screening using electric conductivity. The final useful minerals are again separated by particles in a separate process.

The present invention is a spiral specific gravity screening device used in the primary specific gravity screening process of the entire process of extracting useful minerals from the sea sand. Hereinafter, with reference to the accompanying drawings, it will be described in more detail the spiral specific gravity screening apparatus according to a preferred embodiment of the present invention.

Figure 2 is a schematic perspective view of a spiral specific gravity screening apparatus according to a preferred embodiment of the present invention, Figure 3a is an enlarged perspective view of the main portion of the spiral specific gravity screening device shown in Figure 2, Figure 3b to explain the operation of the air jet device 4 is an enlarged perspective view of a guide member of the spiral specific gravity sorting apparatus shown in FIG. 2.

2 to 4, the spiral specific gravity screening apparatus 100 according to the preferred embodiment of the present invention includes a spiral body 10, a partition member 20, and a blocking member 30.

The spiral body 10 serves as a channel through which a treatment liquid in which sand and water containing useful minerals are mixed flows, and is formed to be long in the vertical direction as a whole, and an inlet part 11 into which the treatment liquid flows in the upper side thereof. Is provided, the lower side is provided with an outlet portion 12 for the treatment liquid flows out. The waterway portion 13 is provided between the inlet portion 11 and the outlet portion 12. In order to support the spiral body 10, the support rod 70 is fitted to the central portion of the spiral body 10.

In addition, the channel 13 of the spiral body 10 is spirally formed so that the processing liquid may be separated by specific gravity in the process of flowing into the inlet 11 of the spiral body 10 and flowing out of the outlet 12. Is formed. That is, since the treatment liquid introduced into the inlet 11 flows toward the outlet 12 while rotating along the channel 13 formed in a spiral shape, particles having a small specific gravity in the treatment liquid due to centrifugal force are transmitted to the channel 13. Gradually pushed outwards along the width direction of the particles, the particles having a high specific gravity remain on the inside along the width direction of the waterway portion (13). Accordingly, the treatment liquids reaching the outlet portion 12 through the waterway portion 13 have heavy particles collected inside the light passage 13 along the width direction of the waterway portion 13, and light particles collected outside. In general, the useful minerals contained in the sand have a higher specific gravity than the constituents of the sand, so that the useful minerals are concentrated inside the outlet part 12.

The outlet part 12 is provided with a partition member 20 so as to separate and discharge the treatment liquids sequentially arranged along the width direction of the waterway part 13 by specific gravity. Although only one partition member 20 may be disposed in the outlet part 12, in this embodiment, two partition members are disposed along the width direction of the outlet part 12, and the treatment liquid is separated into three parts according to specific gravity and discharged. Of course, when more finely divided to separate the treatment liquid, two or more partition members may be disposed.

A guide member 40 having a plurality of guide tubes 41 is provided so that the treatment liquid separated into a plurality of branches by the partition member 20 can be discharged to the outside, respectively. Is installed on the lower side. Each guide pipe 41 is connected to the discharge pipe 42 to guide the treatment liquid to a predetermined reservoir (not shown).

On the other hand, even in the above-described configuration, the treatment liquid may be separated according to specific gravity, but in order to obtain more improved separation efficiency, in the present invention, the intermediate outlet 14 is formed in the channel portion 13 of the spiral body 10. The intermediate discharge port 14 is formed to penetrate the spiral body 10 to discharge a portion of the processing liquid to the outside in the middle of the downward flow along the water channel portion 13 in which the processing liquid descends.

The portion to be discharged through the intermediate discharge port 14 is a portion containing no useful minerals but sand in the treatment liquid. As mentioned above, the useful minerals are located inside the waterway portion 13 in the process of descending along the waterway portion 13 because of their high specific gravity, and the sand is centrifugal force in the process of descending because of its relatively low specific gravity. It pushes outward of the channel part 13 by this. The intermediate discharge port 14 is disposed in the outer side along the width direction of the channel portion 13.

In addition, the intermediate outlet 14 is disposed between the intermediate point and the inlet portion 11 in the entire path of the waterway portion 13, and is formed at the intermediate point of the waterway portion 13 in this embodiment. The reason why it is preferable that the intermediate discharge port 14 is provided at an intermediate point in the entire path of the water channel portion 13 will be described.

The treatment liquid introduced into the inlet portion 11 is not immediately separated by specific gravity, and after at least one rotation along the spiral channel, separation begins according to specific gravity, and the separation rate increases as the number of turns increases. In view of the preliminary removal of the treatment liquid containing concentrated light particles from the waterway portion, the intermediate discharge port 14 is disposed between the outlet portion 12 from a point at which one rotation is completed, and is located on the outlet portion 12 side. It may be desirable. However, when the intermediate outlet 14 is located too far toward the outlet 12, the flow rate for separation of the treatment liquid not discharged from the intermediate outlet 14 again by the specific gravity is reduced, that is, the distance falling while rotating is shortened. The efficiency is rather not improved. Therefore, the intermediate discharge port 14 is most preferably disposed at an intermediate point in the entire path of the waterway portion 13.

A blocking member 30 is provided below the intermediate discharge port 14 on the flow path of the treatment liquid. That is, since the treatment liquid can not continue to be discharged through the intermediate outlet 14 and continue to move along the waterway part 13 when the treatment liquid has a descending speed too fast, immediately after the intermediate outlet 14 to improve the discharge efficiency. Blocking member 30 is installed in the blocking process of the processing liquid. Thus, the blocking member 30 is disposed along the direction of blocking the progress of the processing liquid, that is, along the width direction of the water channel portion, and is disposed to be inclined downward to the outside in the present embodiment.

As described above, the treatment liquid introduced into the inlet portion 11 descends along the waterway portion 13, and after one or two turns is finished, the treatment liquid containing light particles such as sand is concentrated in an intermediate outlet ( 14) is discharged, and the remaining treatment liquid is lowered again along the channel portion (13). In the present invention, the air injection device 60 is provided to increase the separation efficiency of the treatment liquid not discharged from the intermediate discharge port (14).

The air injection device 60 is disposed at the rear end of the intermediate discharge port 14 on the flow path of the processing liquid, and injects air toward the processing liquid. The direction of injecting air injects air in a direction intersecting with the advancing direction of the processing liquid, preferably in a direction perpendicular to the advancing direction of the processing liquid.

The treatment liquid flowing out through the side of the intermediate outlet 14 of the treatment liquid without being discharged to the intermediate outlet 14 is located inside the waterway part 13, and while continuously rotating and descending, the waterway part ( It is spread along the width direction of 13), the air spraying device 60 is to accelerate the action of expanding the treatment liquid according to the specific gravity. That is, when the high-pressure air is injected into the processing liquid perpendicular to the traveling direction, relatively light particles are pushed outward along the width direction of the waterway portion 13, and relatively heavy particles of the waterway portion 13 It remains on the inside to facilitate separation according to specific gravity.

Hereinafter, an example of use of the spiral specific gravity selection device 100 according to the present invention having the above-described configuration will be described.

Water is mixed with sand containing useful minerals, in particular sea sand, to form a treatment liquid, and as shown in the left photograph of FIG. 5A, the treatment liquid is introduced through the inlet 11 of the spiral body 10. Let's do it. The introduced processing liquid is lowered while rotating through the channel portion 13 of the spiral body 10 as shown in the right photograph of FIG. 5A. In this process, particles having a high specific gravity due to centrifugal force are located inside the channel portion 13. Remaining, the small specific gravity is pushed to the outside of the channel portion (13).

Particles pushed outward are guided to a separate guide tube 19 through an intermediate outlet 14 formed at an intermediate point of the spiral body 10, and discharged from the spiral body 10. Even if the treatment liquid has a rapid descending speed, the treatment liquid is blocked by the blocking member 30 so that the treatment liquid containing particles having a small specific gravity is discharged from the spiral body 10.

The treatment liquid containing relatively heavy particles not discharged into the intermediate outlet 14 is continuously descended and separated by specific gravity. The air injection device 60 disposed at the rear of the intermediate outlet 14 is disposed. By injecting air toward the processing liquid, the processing liquid is promoted to be expanded and disposed over the entire width of the water channel portion 13. That is, it accelerates separation by specific gravity.

As shown in FIG. 5B, the treatment liquid reaching the outlet portion 12 of the spiral body 10 has relatively heavy particles concentrated on the inside of the channel 13 and relatively light particles concentrated on the outside. It can be confirmed. In general, heavy particles containing useful minerals are dark in color, and light particles, mainly sand, are white in color. As shown in Figure 5b, it can be seen that the inner side of the waterway portion 13 has a dark color, the outer side has a bright color.

The treatment liquid separated by specific gravity is separated from each other by the partition member 20 and is discharged to the outside through each guide tube 41. Thereafter, the useful mineral may be separated from the seawater through a subsequent process as shown in FIG. 1. In Figure 6 it can be seen a sample picture of several kinds of rare minerals separated from the sea through the above process.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Could be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is a flowchart illustrating a schematic process for extracting useful minerals from seawater.

2 is a schematic perspective view of a spiral specific gravity sorting apparatus according to a preferred embodiment of the present invention.

FIG. 3A is an enlarged perspective view of a main part of the spiral specific gravity sorting apparatus shown in FIG. 2, and FIG. 3B is a schematic view for explaining the operation of the air spray apparatus.

Figure 4 is an enlarged perspective view of the guide member of the spiral specific gravity screening apparatus shown in FIG.

5A and 5B are photographs showing a state of use of the spiral specific gravity selection device shown in FIG. 2.

6 is a sample photograph of several rare minerals separated from sea sand.

<Explanation of symbols for the main parts of the drawings>

100 ... Spiral Specific Grading System 10 ... Spiral Body

11 ... inlet 12 ... outlet

13 ... waterway part 14 ... intermediate outlet

20 ... bulkhead member 30 ... barrier member

40 ... guide member 41 .... guide tube

60 ... air sprayer 70 ... support rod

Claims (8)

A spiral specific gravity screening device for separating the useful minerals from the treatment liquid containing the useful minerals and a mixture of sand and water composed of components having different specific gravity, Longitudinally disposed along the up and down direction, an inlet portion into which the treatment liquid flows in, a water passage portion spirally arranged so that the treatment liquid introduced into the inlet portion rotates downward, and an outlet portion through which the treatment liquid flows out are provided. With the spiral body, And a partition member disposed at the outlet so that the treatment liquid flowing out through the outlet of the spiral body can be separated and discharged into a plurality of branches. Spiral, characterized in that the intermediate discharge port which is disposed on the outside along the width direction of the waterway portion and penetrates the spiral body to remove the relatively small specific gravity in the waterway portion in the waterway portion Specific gravity sorting device. The method of claim 1, And the intermediate discharge port is disposed between an intermediate point of the entire path of the waterway portion and the inlet portion. The method of claim 1, And a blocking member disposed at a rear end of the intermediate discharge port in the traveling direction of the processing liquid along a width direction of the water channel to block the progress of the processing liquid. The method of claim 3, The blocking member is a spiral specific gravity selection device, characterized in that disposed inclined downward toward the outside in the width direction of the waterway portion. The method of claim 1, It is disposed at the rear end of the intermediate discharge port in the advancing direction of the processing liquid, and sprays air toward the processing liquid in a direction intersecting with the traveling direction of the processing liquid so that the processing liquid is widely extended and disposed along the width direction of the channel portion. Spiral specific gravity selection device characterized in that it further comprises an air spraying device. The method of claim 1, Spiral specific gravity sorting device is further provided in the vertical direction, characterized in that it further comprises a support rod is inserted into the central portion of the spiral body to support the spiral body. The method of claim 1, Spiral specific gravity screening device, characterized in that the partition member is disposed so that the two partition walls are spaced apart from each other along the width direction of the channel portion so that the processing liquid passing through the outlet portion. The method of claim 1, And a guide member having a plurality of guide pipes through which the treatment liquid separated into a plurality of branches by the partition member is discharged, respectively.

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