KR20090049741A - Disposal apparatus of wastewater in mine - Google Patents

Abstract

The present invention relates to a mine wastewater treatment apparatus requiring less land, initial investment and maintenance costs by simplifying the configuration of the mine wastewater treatment apparatus.

The present invention is a mine wastewater treatment apparatus, comprising: a flow rate adjusting tank (10) into which a mine wastewater flows; An oxidation tank 20 in which the flow rate of water discharged from the flow rate adjustment tank 10 is stored; An ozone stirrer 30 for supplying ozone from the oxidizing tank 20; A first filtration unit 40 filtering sludge from the oxidized water oxidized in the oxidizing tank 20 to discharge the filtered water; A second filter part 50 for filtering the fine sludge from the filtered water discharged from the first filter part 40; It includes a discharge tank 60 in which the filtered water filtered in the second filtration unit 50 is collected.

The present invention has the advantage that the mine wastewater can be purified by treating iron, manganese, aluminum and hardly decomposable substances in the mine wastewater.

Mine Wastewater, Ozone, Ultraviolet Light, Iron, Manganese, Aluminum, Sludge, Backwash

Description

Mine Wastewater Treatment System {DISPOSAL APPARATUS OF WASTEWATER IN MINE}

1 is a cross-sectional view showing a mine wastewater treatment apparatus by a physicochemical method used in the prior art.

Figure 2 is a block diagram of a mine wastewater treatment apparatus according to an embodiment of the present invention.

<Brief Description of Drawings>

10: flow rate adjusting tank 20: oxidation tank

30: ozone stirrer 40: first filter

50: second filter 60: discharge tank

70: UV supply 80: back detail

The present invention relates to a mine wastewater treatment apparatus.

At present, about 350 abandoned mines nationwide are not operating facilities to prevent outflow from the mines or the prevention facilities are insufficient. Therefore, the environmental pollution problem of mine wastewater flowing out from such abandoned mines is seriously raised. It is becoming.

In addition to the abandoned mines, current coal mines are also being abandoned due to deterioration in profitability and reduced demand for coal, and the mine wastewater discharges harmful substances such as sulphates into the rivers while eluting heavy metals into the surrounding soil. It is recognized as a major contaminant of water, groundwater, and soil, such as generating sediment.

Mine wastewater is acidic wastewater with pH 2-6 and contains sulfide minerals and heavy metals such as Fe, Al, and Mn. Especially, Fe component suspended or dissolved while occupying about 82% by weight of heavy metals in wastewater is the main cause of pollution. It is working.

Currently, mine wastewater treatment methods that are applied to the abandoned mines include artificial marsh land method and physicochemical method, and artificial marsh land method is mainly used.

Artificial marsh land method is a method widely used in Europe and the like as a method of depositing hydroxide according to the pH change of the mine wastewater introduced by making artificial pond in a certain place.

However, in Korea, there is a problem in that the treatment efficiency does not appear constant because the amount of sunshine, precipitation, temperature, etc. vary greatly depending on the season. In addition, there is a big problem that the sludge precipitated in the artificial marsh land in the rainy season again flows into the river, due to the disadvantages such as the site requirements and the continuity of the waste water treatment, the artificial marsh land method is not applied anymore.

The physicochemical method is a method of neutralizing mine wastewater and removing heavy metals by adding an alkaline neutralizer, and is currently operated in two places in Korea.

1 is a cross-sectional view showing a mine wastewater treatment apparatus by the physicochemical method currently used.

As shown in FIG. 1, the mine wastewater is purified by sequentially passing through a pH adjusting tank 1, an aeration tank 2, a neutralization tank 3, a coagulation tank 4, a precipitation tank 5, and a discharge tank 6. And then discharged.

In the pH adjusting tank 1, ferrous sulfate (FeSO ₄ ) is added as an oxidizing agent, and in the aeration tank 2, excessive aeration is performed to form a precipitate of Fe (OH) _{3 as} a hydroxide while oxidizing Fe ²⁺ ions to Fe ³⁺ ions. Fe can be removed more effectively.

In addition, the neutralizing agent used in the neutralization tank 3 uses caustic soda (NaOH) or liquid lime (Ca (OH) ₂ ).

The mine wastewater treatment apparatus by the physical and chemical method is the most efficient treatment among the mine wastewater treatment method currently operating, but has a very low utilization due to the cost problems and excessive management costs due to the use of chemicals such as oxidants.

On the other hand, the prior art associated with the present invention has been proposed as follows.

Korean Utility Model Model No. 20-0329033 (registered date: September 25, 2003), which is one of the prior arts, will be described below.

Conventional mine wastewater treatment apparatus includes a reaction tank in which the mine wastewater is introduced, and an underwater stirrer is installed below the water surface of the mine wastewater; Agglomeration tank into which wastewater from the reactor is introduced; A sedimentation tank into which wastewater from the flocculation tank is introduced; And a discharge tank into which the wastewater from the sedimentation tank is introduced, and the underwater stirrer includes a neutralizer inlet tube installed to protrude above the water surface of the mine wastewater so that the neutralizer is introduced from the outside.

However, the conventional mine wastewater treatment apparatus is to treat the wastewater by adding a neutralizing agent, there is a problem that takes the neutralizing agent as much as the amount of wastewater treatment.

The present invention has been made to solve the problems of the prior art, an object of the present invention is to provide a mine wastewater treatment apparatus that requires less site, initial investment and maintenance costs by simplifying the configuration of the mine wastewater treatment apparatus. .

Another object of the present invention to provide a mine wastewater treatment apparatus capable of treating iron, manganese, aluminum and hardly decomposable substances contained in the mine wastewater.

In accordance with an aspect of the present invention, there is provided a mine wastewater treatment apparatus, including: a flow rate adjusting tank into which a mine wastewater flows; An oxidation tank for storing the flow rate water discharged from the flow rate adjustment tank; An ozone stirrer for supplying ozone from the oxidizing tank; A first filtration unit for filtering the sludge from the oxidized water oxidized in the oxidizing tank to discharge the filtered water; A second filtration unit for filtering fine sludge from the filtered water discharged from the first filtration unit; It includes a discharge tank for collecting the filtered water filtered in the second filtration unit.

Hereinafter, embodiments of the present invention will be described based on the drawings.

2 is a block diagram of a mine wastewater treatment apparatus according to an embodiment of the present invention.

As shown in Figure 2, the present invention, in the mine wastewater treatment apparatus, the flow rate adjusting tank 10 to which the mine wastewater flows; An oxidation tank 20 in which the flow rate of water discharged from the flow rate adjustment tank 10 is stored; An ozone stirrer 30 for supplying ozone from the oxidizing tank 20; A first filtration unit 40 filtering sludge from the oxidized water oxidized in the oxidizing tank 20 to discharge the filtered water; A second filter part 50 for filtering the fine sludge from the filtered water discharged from the first filter part 40; It includes a discharge tank 60 in which the filtered water filtered in the second filtration unit 50 is collected.

Here, the mine wastewater flows into the flow rate adjustment tank 10 and is stored. At this time, the inflow water flows into the flow regulating tank 10 is supplied to the ozone stirrer 30 by the flow pump 11. At this time, inflow water and ozone are mixed and supplied to the oxidizing tank 20 by the ozone stirrer 30. The ozone stirrer 30 receives ozone from an external ozone supply 31.

Subsequently, iron and manganese are oxidized by ozone, and the inflow water supplied to the oxidizing tank 20 through the ozone stirrer 30 is first purified. Here, since the ozone stirrer 30 rapidly mixes ozone and water, iron and manganese may be rapidly oxidized. Therefore, since rapid oxidation is performed by the ozone stirrer 30, a separate storage tank is not necessary.

At this time, the movement passage 12 is formed in the flow rate adjustment tank 10. When the flow passage 12 has less inflow into the flow regulating tank 10 so that the flow regulating tank 10 is not filled with water, the oxidized water oxidized in the oxidizing tank 20 is supplied to the flow regulating tank 10 again. You can do that.

When both the flow rate adjusting tank 10 and the oxidizing tank 20 are filled with water, the oxidizing water is supplied from the oxidizing tank 20 to the first filtration unit 40.

The first filtration unit 40 preferably includes a sand layer 42 to remove sludge.

Here, the oxidized water supplied from the oxidizing tank 20 is filtered in the sand layer 41 of the first filtration unit 40 to filter the sludge. The filtered water filtered by the first filtration part 40 by the first pump 41 is supplied to the second filtration part 50.

The second filtration unit 50 preferably includes an activated carbon layer 52 to remove fine sludge.

Here, the fine sludge is filtered by the second filtration unit 50 of the second filtration unit 50 filtered water from the first filtration unit 40. The filtered water filtered again in the second filtration unit 50 may be discharged after being stored in the discharge tank 60.

In addition, the filtered water filtered by the second filtration unit 50 by the second pump 51 may be supplied to the ultraviolet light supplier (70).

It is preferable to further include a UV supplier 70 for supplying ultraviolet light to the discharge tank (60).

Here, the ultraviolet light supply 70 may oxidize aluminum by supplying ultraviolet light to the filtered water supplied by the second pump 51.

The oxidized water oxidized by the UV supplier 70 may be discharged after being stored in the discharge tank 60.

At this time, the ozone stirrer 30 'is further installed between the second pump 51 and the UV supplier 70 to further oxidize iron and manganese which may remain by supplying ozone once more to the filtered water. have. In addition, the ozone stirrer 30 'and the ultraviolet light supply 70 may also oxidize aluminum and dioxins, which are hardly decomposable substances.

It is preferable to further include a backwashing part 80 for backwashing the effluent of the discharge tank 60 to remove the sludge filtered by the first filtration part 40 and the second filtration part 50.

Here, the backwashing unit 80 may backwash the effluent of the discharge tank 60 to remove the sludge filtered by the first filtration unit 40 and the second filtration unit 50.

The backwashing unit (80) includes a backwash pump (81) for backwashing the discharge water of the discharge tank (60) to the first filtration unit (40) and the second filtration unit (50); A transfer pump (83) for transferring the backwashed water backwashed by the first filtration unit (40) and the second filtration unit (50) by pumping the backwash pump (81); A sludge dewatering unit 85 for dewatering sludge from the backwash water conveyed by the transfer pump 83; It is preferable to include the conveyance pump 87 which conveys the water dewatered by the sludge dewatering part 85 to the said flow regulating tank 10.

Here, when the effluent of the discharge tank 60 is backwashed by the backwash pump 81, the sludge filtered by the first filtration unit 40 and the second filtration unit 50 is suspended together with the backwash water.

At this time, when the conveying sludge and the backwash water are transferred to the sludge dewatering part 85, the sludge dewatering part 85 performs dehydration to filter the sludge. As such, the dewatered sludge is treated separately.

The separated water is again conveyed to the flow rate adjusting tank 10 and reprocessed.

As such, the present invention can be treated by oxidizing iron, manganese and aluminum in the mine wastewater. In addition, the sludge contained in the influent may be dewatered and treated separately.

As described above, in the detailed description of the present invention, specific embodiment (s) have been described, but various modifications are possible without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiment (s), but should be defined by the claims below and equivalents thereof.

The present invention simplifies the construction of the mine wastewater treatment apparatus, that is, ozone and water are rapidly stirred by the ozone stirrer, and contaminants of the wastewater are rapidly oxidized, so that no sedimentation tank or storage tank is required. Therefore, there is an advantage that the required site, the initial investment costs and maintenance costs are less.

In addition, the present invention has the advantage of treating iron, manganese, aluminum and hardly decomposable substances in the mine wastewater.

In addition, the present invention has the advantage of reducing the amount of sludge by oxidizing iron, manganese, aluminum and hardly decomposable substances in the mine wastewater.

In addition, the present invention does not require an input device for adding a neutralizing agent, a polymer flocculant, slaked lime and the like.

Claims (6)

In the mine wastewater treatment apparatus, A flow rate adjusting tank 10 into which the mine wastewater flows; An oxidation tank 20 in which the flow rate of water discharged from the flow rate adjustment tank 10 is stored; An ozone stirrer 30 for supplying ozone from the oxidizing tank 20; A first filtration unit 40 filtering sludge from the oxidized water oxidized in the oxidizing tank 20 to discharge the filtered water; A second filter part 50 for filtering the fine sludge from the filtered water discharged from the first filter part 40; Mine wastewater treatment apparatus including a discharge tank 60 for collecting the filtered water filtered in the second filtration unit (50). 2. The mine wastewater treatment apparatus according to claim 1, wherein the first filtration unit (40) includes a sand layer (42) to remove sludge. The mine wastewater treatment apparatus according to claim 1, wherein the second filtration unit (50) comprises an activated carbon layer (52) to remove fine sludge. The mine wastewater treatment apparatus according to claim 1, further comprising an ultraviolet lighter (70) for supplying ultraviolet rays to the discharge tank (60). The apparatus of claim 1, further comprising a backwashing portion (80) for backwashing the effluent of the discharge tank (60) to remove sludge filtered from the first filtration portion (40) and the second filtration portion (50). Mine wastewater treatment apparatus, characterized in that. The method of claim 1, wherein the backwashing portion 80 A backwash pump (81) for backwashing the discharge water of the discharge tank (60) to the first filtration unit (40) and the second filtration unit (50); A transfer pump (83) for transferring the backwashed water backwashed by the first filtration unit (40) and the second filtration unit (50) by pumping the backwash pump (81); A sludge dewatering unit 85 for dewatering sludge from the backwash water conveyed by the transfer pump 83; And a conveying pump (87) for conveying the water dewatered from the sludge dewatering unit (85) to the flow rate adjusting tank (10).

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