KR102012438B1 - Waste Water Treatment Device - Google Patents

Abstract

The present invention relates to a wastewater treatment apparatus. The wastewater treatment apparatus of the present invention comprises: a sedimentation tank into which contaminated water is introduced; an acid adjustment tank for adjusting pH of the contaminated water introduced from the sedimentation tank; a carbon dioxide supply unit for injecting carbon dioxide gas into the acid adjustment tank; a pumping tank storing the contaminated water having pH adjusted in the acid adjustment tank; and a treatment tank receiving the contaminated water from the pumping tank and treating the contaminant contained in the contaminated water. The wastewater treatment apparatus according to the present invention neutralizes alkaline wastewater by quickly and simply adjusting pH using carbon dioxide gas.

Description

Waste Water Treatment Device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wastewater treatment apparatus, and more particularly, to a wastewater treatment apparatus capable of neutralizing treatment by adjusting the pH of alkaline wastewater using carbon dioxide gas.

In the treatment of contaminated water, it is common to introduce a flocculant into a contaminant contained in the contaminated water so that the contaminant and the flocculant react to form flocs and a flocculation tank to precipitate the flocs.

By the way, the wastewater which generate | occur | produces in a construction site or an industrial factory is generally a large quantity of alkaline wastewater, and is highly alkaline and high alkaline. Neutralization treatment is important for the treatment of such wastewater. The wastewater may be neutralized to increase the efficiency of subsequent flocculation and precipitation.

The present invention is to propose a wastewater treatment apparatus that can quickly and easily perform the neutralization treatment of alkaline wastewater.

Patent Registration No. 10-1800290

The present invention has been made to solve the above problems, and an object of the present invention is to provide a wastewater treatment apparatus that can be neutralized by quickly and simply adjusting the pH of alkaline wastewater using carbon dioxide gas.

Wastewater treatment apparatus according to the present invention, the sedimentation tank into which the contaminated water flows; An acid adjustment tank for adjusting pH of the contaminated water introduced from the settling tank; A carbon dioxide gas supply unit for injecting carbon dioxide gas into the acid adjustment tank; A pumping tank storing contaminated water having a pH adjusted in the acid adjusting tank; And a treatment tank receiving the contaminated water from the pumping tank and treating the contaminant contained in the contaminated water.

In addition, the carbon dioxide gas supply unit, a plurality of reservoirs for storing the carbon dioxide gas; A first sensor sensing a pH of the contaminated water introduced into the acid adjustment tank; And a controller for controlling the amount of the carbon dioxide gas supplied from each reservoir to the acid adjustment tank based on the pH information of the contaminated water received from the first sensor.

In addition, the carbon dioxide gas supply unit preferably includes a display unit for displaying information on the residual amount of carbon dioxide gas stored in each storage bin to the outside.

In addition, it is preferable that each reservoir is replaceable.

In addition, the storage tank for storing the pH adjuster containing aluminum sulfate; A second sensor for sensing a pH of the contaminated water introduced into the acid adjustment tank; And a supply amount adjusting unit for controlling the amount of the pH adjusting agent supplied from the storage tank to the acid adjusting tank based on the pH information of the contaminated water received from the second sensor.

In addition, the treatment tank preferably includes an agglomeration tank for reacting a contaminant contained in the contaminated water with a flocculant to form a floc, and a precipitation tank in which the contaminated water flows from the agglomeration tank to precipitate the pollutant.

In addition, the air supply unit extending to the bottom surface of the acid adjustment tank and having a plurality of ejection holes formed; air supply unit; wherein the carbon dioxide gas is preferably supplied to the acid adjustment tank with the air through the air supply pipe.

In addition, it comprises a storage tank for storing a pH adjusting agent containing aluminum sulfate, the pH adjusting agent is preferably introduced to the top of the acid adjusting tank.

The wastewater treatment apparatus according to the present invention provides an effect of neutralizing the alkaline wastewater by quickly and simply adjusting the pH using carbon dioxide gas.

In addition, a plurality of reservoirs for storing carbon dioxide gas is provided, and each reservoir is provided to be replaceable, thereby providing an effect of continuously injecting carbon dioxide gas.

In addition, since the remaining amount of each storage bin for storing carbon dioxide gas can be confirmed by the display unit, the storage bin that needs to be replaced can be identified and quickly replaced, thereby providing an effect of improving work efficiency.

In addition, the carbon dioxide gas is connected to the air supply having a plurality of ejection holes and supplied with the air, thereby providing an effect of promoting the neutralization reaction in the acid adjustment tank.

In addition, since the wastewater treatment apparatus according to the present invention uses carbon dioxide and aluminum sulfate together to adjust the pH of the contaminated water, it is possible to quickly and effectively neutralize the contaminated water.

1 is a schematic diagram of a wastewater treatment apparatus according to an embodiment of the present invention;
2 is a block diagram illustrating a wastewater treatment flow.
3 is a flowchart illustrating a process in which carbon dioxide gas is supplied by a controller.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a system diagram of a wastewater treatment apparatus according to an embodiment of the present invention, Figure 2 is a block diagram showing the wastewater treatment flow. 3 is a flowchart illustrating a process in which carbon dioxide gas is supplied by a controller.

Wastewater treatment apparatus according to an embodiment of the present invention, for treating alkaline contaminated water generated in the construction site or industrial plant. For example, the present invention can be used to treat alkaline contaminated water generated during tunnel construction.

First, referring to Figure 1, the wastewater treatment apparatus according to the embodiment of the present invention, the sedimentation tank 10, acid adjustment tank 20, carbon dioxide gas supply unit 30, pumping tank 40, and treatment tank 50 It includes.

The sedimentation tank 10 is provided to remove contaminants that can be removed by natural sedimentation among contaminants contained in alkaline contaminated water. Among the particulate contaminants such as sand and soil contained in the contaminated water introduced into the sedimentation tank 10, the pollutants that can be naturally settled by gravity sink to the bottom of the sedimentation tank 10.

The acid adjustment tank 20 is provided to adjust and neutralize the pH of the contaminated water introduced from the sedimentation tank 10. The upper portion of the acid adjustment tank 20 is connected to the upper portion of the immersion tank 10, the contaminated water flows from the upper portion of the immersion tank (10).

The carbon dioxide gas supply unit 30 is provided to inject carbon dioxide gas into the acid adjustment tank 20. According to the present embodiment, the carbon dioxide gas supply unit 30 includes a reservoir 31, a first sensor 32, a controller 33, and a display unit 43.

The reservoir 31 is provided to store the carbon dioxide gas, according to the present embodiment, a plurality of the reservoir 31 is provided. Since each of the reservoirs 31 are provided to be replaceable, when all of the carbon dioxide stored in one of the reservoirs 31 is supplied to the acid adjustment tank 20, the carbon dioxide stored in the other reservoirs 31 may be continuously supplied. have.

According to this embodiment, since the plurality of storage bins 31 are provided in a small size, it is implemented to easily transfer and replace them individually while sufficiently securing the overall amount of carbon dioxide.

The first sensor 32 senses the pH of the contaminated water introduced into the acid adjustment tank 20. The information measured by the first sensor 32 is provided to the controller 33.

The controller 33 controls the amount of the carbon dioxide gas supplied from the reservoir 31 to the acid adjustment tank 20 based on the pH information of the contaminated water received from the first sensor 32.

The controller 33 may control the carbon dioxide gas stored in one reservoir 31 into the acid adjustment tank 20, or control the carbon dioxide gas stored in the plurality of reservoirs 31 to be simultaneously introduced into the acid adjustment tank 20. Can be.

That is, the controller 33 may supply the carbon dioxide gas stored in one reservoir 31 to the acid adjustment tank 20, and maintain the remaining reservoir 31 in the standby state. Alternatively, the controller 33 may simultaneously control the carbon dioxide gas stored in two or more reservoirs 31 into the acid adjustment tank 20, and maintain the remaining reservoirs 31 in the standby state.

The display unit 34 is provided to externally display information on the remaining amount of carbon dioxide gas stored in each storage container 31. The display unit 34 identifies each reservoir 31 and displays the residual amount of carbon dioxide gas stored in the reservoir 31. By referring to the display unit 34, the user grasps and replaces the reservoir 31 that needs to be replaced, so that the carbon dioxide gas can be continuously introduced into the acid adjustment tank 20.

The pumping tank 40 stores the contaminated water whose pH is adjusted in the acid adjusting tank 20 before the contaminated water flows into the treatment tank 50. The pumping tank 40 is provided with a pump 41 for pumping the contaminated water into the treatment tank 50.

According to the present embodiment, the surface of the contaminated water stored in the pumping tank 40 is lower than the surface of the contaminated water flowing into the treatment tank 50. Therefore, the pumping tank 40 pumps and transports the contaminated water to the treatment tank 50.

The treatment tank 50 is provided to receive the contaminated water from the pumping tank 40 to remove and treat contaminants contained in the contaminated water. Specifically, the treatment tank 50 includes a flocculation tank 51 and a precipitation tank 52.

The coagulation tank 51 is provided to react the pollutants contained in the contaminated water with the coagulant to form flocs. According to this embodiment, a flocculant storage tank 100 for introducing a polymer flocculant into the flocculation tank 51 is provided. The polymer flocculant is introduced into the flocculation tank 51 from the flocculant storage tank 100 by a supply pump 110. Since the said flocculant uses a well-known thing, the detailed description is abbreviate | omitted.

The settling tank 52 is provided to allow the polluted water to flow from the coagulation tank 51 to precipitate the pollutant. According to this embodiment, the settling tank 51 includes an inner cylinder 511 and an outer cylinder 512.

The inner cylinder 511 is provided at the center side of the settling tank 52 so that the contaminated water flows in. An inlet pipe 53 connecting the upper portion of the inner cylinder 511 and the coagulation tank 51 is provided, and the contaminated water is introduced into the upper side of the inner cylinder 511 through the inlet tube 53 and moves downward. Flow. The lower end of the inner cylinder 511 is provided with a guide plate 513 inclined downward toward the inner circumferential surface of the outer cylinder 512.

An end portion of the guide plate 513 is spaced apart from the inner circumferential surface of the outer cylinder 512, and forms a flow path of the contaminated water when the contaminated water is filled up from the lower end of the outer cylinder 512. In addition, the guide plate 513 prevents the floc contained in the contaminated water from rising to the upper side of the outer cylinder 512, and can be settled down.

The outer cylinder 512 is disposed outside the inner cylinder 511, and has a lower end inclined surface 514 inclined downward toward the center side. The naturally sedimenting contaminants move downward along the inclined surface 514. At the lower end of the center side of the outer cylinder 512, a hopper portion 515 is provided to collect the settled contaminants. When contaminants are accumulated at a predetermined level in the hopper 515, the contaminants are periodically discharged to the outside through the dehydrator 120.

The overflow part 516 is provided above the outer cylinder 512. The overflow portion 516 is a space in which the treated water contaminated with contaminants from the contaminated water is filled up from the lower end of the outer cylinder 512 and collected and collected in the overflow portion 516 to discharge the discharge pipe 517. After moving to the discharge tank 130 through, it is discharged to the outside.

According to the embodiment of the present invention, the storage tank 60, the second sensor 70, the supply amount adjusting unit 80, air supply unit 90 is included.

The storage tank 60 is a tank for storing a pH adjusting agent containing aluminum sulfate in order to promote the neutralization reaction of contaminated water. According to this embodiment, since the pH adjusting agent including aluminum sulfate is used together with the carbon dioxide gas for the neutralization reaction of the contaminated water, it provides an effect of promoting the neutralization reaction.

In addition, according to the present embodiment, the carbon dioxide gas is supplied to the lower portion of the acid adjustment tank 20, the pH adjuster is supplied to the upper side of the acid adjustment tank 20, the neutralization reaction in the acid adjustment tank 20 This is to occur as a whole to effectively cause the neutralization reaction.

The second sensor 70 senses the pH of the contaminated water introduced into the acid adjustment tank 20. The pH information of the contaminated water measured by the second sensor 70 is transmitted to the supply amount adjusting unit 80.

Referring to FIG. 1, although the second sensor 70 is illustrated as being separately provided from the first sensor 32, one sensor may be provided to measure the pH of the acid adjustment tank 20. The pH information of the contaminated water measured by the sensor may be provided to the controller 33 and the supply amount adjusting unit 80.

The supply amount adjusting unit 80 adjusts the amount of the pH adjusting agent supplied from the storage tank 60 to the acid adjusting unit 20 based on the pH information of the contaminated water received from the second sensor 70. To control.

The air supply unit 90 supplies air where air supply is necessary in the present system, and mixes in contaminated water to improve a purification function. According to this embodiment, air is supplied to the acid adjustment tank 20, the pumping tank 30, the storage tank 60, the flocculation tank 51, the flocculant storage tank 100.

The air supply unit 90 includes an air supply pipe 91 extending to the bottom of the acid adjustment tank 20 and having a plurality of ejection holes 911. According to this embodiment, the carbon dioxide gas is supplied to the acid adjustment tank 20 together with the air through the air supply pipe 91. In addition, according to the present embodiment, the air supply pipe 91 extends to the bottom surface of the pumping tank 30, the storage tank 100, the flocculation tank 51, and the flocculant storage tank 100.

Hereinafter, the operation to effect of the present invention according to the above configuration will be described in detail.

Referring to FIG. 2, the contaminated water is purified while passing through the sedimentation tank 10, the acid adjustment tank 20, the pumping tank 30, the coagulation tank 51, and the settling tank 52, and the discharge tank 130. Discharged through. The contaminated water is, for example, highly alkaline wastewater generated during tunnel construction, and is neutralized to remove contaminants contained in the wastewater.

Specifically, heavy contaminants such as sand and soil included in the contaminated water introduced into the sedimentation tank 10 are removed while being naturally settled in the sedimentation tank 10. Subsequently, the wastewater introduced into the acid adjustment tank 20 is neutralized while reacting with a pH adjuster including carbon dioxide and aluminum sulfate.

Referring to FIG. 3, the controller 33 introduces carbon dioxide gas into the acid adjustment tank 20 from the selected reservoir 31. In this case, the inflow amount of the carbon dioxide gas is adjusted by the controller 33 based on the pH information of the contaminated water sensed by the first sensor 32. The carbon dioxide gas is introduced into the lower portion of the acid adjustment tank 20 together with the air through the air supply pipe 91.

The control unit 33 checks the remaining amount of the stored carbon dioxide gas in the supply container 31 being supplied, and determines whether replacement is necessary. If the residual amount is sufficient, the carbon dioxide gas of the reservoir 31 is continuously supplied. When it is determined that replacement of the storage container 31 is necessary, the carbon dioxide gas stored in the new storage container 31 is introduced into the acid adjustment tank 20 from among the plurality of storage containers 31 provided.

By repeating this process, the supply of carbon dioxide gas is not interrupted and the neutralization reaction occurs continuously in the acid adjustment tank 20. Since the reservoir 31 may be implemented in a relatively small size, it is possible to eliminate the inconvenience of manufacturing and installing a large-capacity tank for storing carbon dioxide gas. Of course, the controller 33 may supply the carbon dioxide gas stored in the plurality of reservoirs 31 to the acid adjustment tank 20 together.

On the other hand, the pH adjusting agent containing aluminum sulfate stored in the storage tank 60 is introduced into the acid adjusting tank 20 through the supply amount adjusting unit 80. At this time, the pH adjusting agent is introduced into the upper portion of the acid adjusting tank (20). The pH adjuster is used in the neutralization reaction of the waste water together with the carbon dioxide gas to promote the neutralization reaction.

In addition, the pH regulator is introduced into the upper portion of the acid adjusting tank 20, the carbon dioxide gas is introduced into the lower portion of the acid adjusting tank 20 to improve the efficiency of the neutralization reaction in the entire space inside the acid adjusting tank 20. You can.

After neutralization is completed in the acid adjustment tank 20, the contaminated water moves to the pumping tank 30. The pump 31 of the pumping tank 30 pumps the contaminated water into the coagulation tank 51. In the settling tank 52, the floc is removed by natural sedimentation, so that the surface of the flocculating tank 51 and the settling tank 52 is higher than the pumping tank 30. Therefore, the wastewater is pumped from the pumping tank 30 to the coagulation tank 51.

The polymer flocculant is introduced into the contaminated water flowing into the flocculation tank 51. The contaminant contained in the contaminated water reacts with the flocculant to form a floc, and the contaminated water having the floc flows to the settling tank 52. The floc naturally precipitates in the settling tank 52, and the treated water from which the floc has been removed rises between the inner cylinder 511 and the outer cylinder 512 and is moved to the overflow part 516, and then passes through the discharge tank 130. Discharged. On the other hand, the floc accumulated in the hopper 515 of the settling tank 52 is periodically processed through the dehydrator 120.

As such, in the wastewater treatment apparatus according to the embodiment of the present invention, when neutralizing alkaline wastewater using a pH adjuster including carbon dioxide and aluminum sulfate, a plurality of reservoirs for storing carbon dioxide are provided, and each reservoir is replaceable. Therefore, it provides an effect that can continuously inject carbon dioxide gas.

In addition, the remaining amount of each storage bin for storing the carbon dioxide gas can be confirmed by the display unit, and the storage bin that needs to be replaced can be identified and quickly replaced, thereby providing an effect of improving work efficiency.

In the above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and many other modifications may be provided without departing from the scope of the present invention.

10 ... tide tank 20 ... mountain adjustment tank
30 ... carbon dioxide gas supply unit 31 ... reservoir
32 ... First sensor 33 ... Control unit
34 ... indicator 40 ... pumping tank
41 pump 50 treatment tank
51 ... flocculation tank 52 ... sedimentation tank
53 ... Inlet 511 ... Inner tube
512 ... External 513 ... Guide plate
514. Slope 515 ... Hopper section
516 ... Overflow section 517 ... Exhaust piping
60 ... Storage tank 70 ... Second sensor
80 ... Supply control part 90 ... Air supply part
91.Air supply line 911
100 ... flocculant storage tank 110 ... supply pump
120 ... dehydrator 130 ... discharge tank

Claims (8)

A sedimentation tank 10 into which contaminated water is introduced;
Acid adjustment tank 20 for adjusting the pH of the contaminated water introduced from the sedimentation tank (10);
A carbon dioxide gas supply unit 30 for injecting carbon dioxide gas into the acid adjustment tank 20;
A pumping tank 40 for storing contaminated water having a pH adjusted in the acid adjusting tank 20;
A treatment tank 50 receiving the contaminated water from the pumping tank 40 to process to remove contaminants contained in the contaminated water; And
It includes; a storage tank for storing the pH adjuster containing aluminum sulfate;
The carbon dioxide gas is introduced into the lower portion of the acid adjusting tank 20, the pH adjusting agent is introduced into the upper portion of the acid adjusting tank 20,
The treatment tank 50, a flocculation tank 51 for reacting the contaminants contained in the contaminated water with a flocculant to form a floc, and the contaminated water flows from the flocculation tank 51 to precipitate the contaminants. A settling tank 52,
The settling tank 52,
An inner cylinder 511 provided at the center side; An inlet pipe 53 connected to the agglomeration tank 51 and provided at an upper portion of the inner cylinder 511 to allow contaminated water to flow therein; A guide plate 513 coupled to the lower end of the inner cylinder 511 to be inclined downward; And an outer cylinder 512 spaced apart from an end of the guide plate 513 and disposed outside the inner cylinder 511.
The contaminated water flows into the upper portion of the inner cylinder 511 and is settled downward, between the inner cylinder 511 and the outer cylinder 512 via the guide plate 513 and the outer cylinder 512. Flow upwards,
The carbon dioxide gas supply unit 30,
A plurality of reservoirs 31 storing carbon dioxide gas;
A first sensor 32 for sensing the pH of the contaminated water introduced into the acid adjustment tank 20;
A controller (33) for controlling the amount of carbon dioxide gas supplied from each of the reservoirs (31) to the acid adjustment tank (20) based on the pH information of the contaminated water received from the first sensor (32); And
And a display unit 34 which displays information on the residual amount of carbon dioxide gas stored in each storage container 31 to the outside.
Each reservoir 31 is a wastewater treatment apparatus, characterized in that replaceable. delete delete delete The method of claim 1,
A second sensor (70) for sensing the pH of the contaminated water introduced into the acid adjustment tank (20);
Supply amount adjusting unit 80 for controlling the amount of the pH adjuster supplied from the storage tank 60 to the acid adjustment tank 20 based on the pH information of the contaminated water received from the second sensor 70 Wastewater treatment apparatus comprising a. delete The method of claim 1,
And an air supply unit 90 extending to the bottom of the acid adjustment tank 20 and having an air supply pipe 91 having a plurality of ejection holes 911.
The carbon dioxide gas is supplied to the acid adjustment tank (20) together with air through the air supply pipe (91). delete

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