KR20180091549A - Water Purification Device - Google Patents

Abstract

The present invention relates to a water purification apparatus applied with concentrated aeration, which comprises: an air inflow pipe for receiving air from a blower; an air compression pipe for receiving the air from the air inflow pipe; a plurality of air induction pipes downwardly installed in the air compression pipe to downwardly flow the air provided from the air compression pipe; a diffuser installed at a lower end of the air induction pipes to change the downwardly flowing air into micro-bubbles; a concentrated aeration pipe having an inner diameter thereof formed to be greater than an outer diameter of the air induction pipes to surround the air induction pipes and the diffuser; a wastewater inflow pipe installed at a lower side of the concentrated aeration pipe to be positioned in a wastewater, and formed with a plurality of inflow holes in which the wastewater is introduced; and a gas-liquid compression pipe installed at an upper end of the concentrated aeration pipe, and formed with a discharge hole at a predetermined interval. Accordingly, dissolved oxygen of wastewater can be remarkably increased, thereby easily decomposing contaminants.

Description

{Water Purification Device}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water purification apparatus, and more particularly, to a water purification apparatus using an intensive aeration capable of easily removing contaminants and facilitating maintenance and management.

Since pollutants such as reservoirs and lakes can not be replaced easily and the circulation of water is not smooth, contaminated water and sewage are continuously introduced into sewage, sewage, factory sewage, agricultural and wastewater, etc., .

In particular, nutrient salts including nitrogen compounds and phosphates in pollutants cause eutrophication in fresh water because they promote the growth and proliferation of microorganisms causing decomposition of organic matter.

Therefore, it is important to maintain balance in the closed water body so that the amount of nutrients such as nitrogen and phosphorus contained in the aquatic ecosystem does not exceed the self-purification capacity. In particular, it is important to maintain the balance of organic matter and heavy metals, It is very important to ensure that this is done smoothly.

However, many dams, reservoirs and lakes in Korea are still experiencing deterioration of water quality due to the introduction of large amounts of pollutants and the formation of dense layers according to long - term fresh water despite the increase of wastewater purification facilities.

Application No.: 10-2015-0042485 (Publication No.: 10-2016-0115235, entitled: Apparatus and Method for Manufacturing Environmentally Friendly Organic Culture Medium

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide an intensive aeration system capable of remarkably increasing dissolved oxygen by concentrated aeration of wastewater, The present invention is directed to a water purification apparatus to which the present invention is applied.

According to an aspect of the present invention, there is provided an apparatus for purifying water, the apparatus including: an air inlet pipe for receiving air from a blower; An air pressure shaft for receiving air from the air inlet pipe; A plurality of air induction pipes installed downwardly on the air pressure shaft pipe to allow the air supplied from the air pressure shaft pipe to flow downward; A diffuser installed at a lower end of the air induction pipe and converting the air flowing downward into a fine particle; An intensifying bore having an inner diameter larger than an outer diameter of the air induction pipe to surround the air induction pipe and the diffuser; A wastewater inlet pipe installed in the wastewater below the concentrated wastewater and having a plurality of inlet holes into which wastewater flows; Wherein the wastewater flowing through the inflow hole flows upward in a space between the air induction pipe and the concentrated intensifying mechanism, Is concentratedly aerated by fine bubbles generated by the diffuser, and then sprayed onto the surface of the water through the discharge port.

Here, an extension pipe is provided at the discharge port of the vapor-liquid pressure shaft pipe, and the extension pipe is bent or rounded at a predetermined curvature.

The apparatus for purifying water using the intensive aeration of the present invention as described above can dramatically increase the dissolved oxygen of the wastewater by the concentration aeration to promote the proliferation of aerobic microorganisms. As a result, BOD, SS, There is an advantage that the pollutant can be easily decomposed.

Further, since the deep wastewater is naturally pumped by the rising buoyancy of the air acting in the intensive-width engine and supplied to the inside of the intensive-width engine, not by the separate electric drive device such as a pump, Cost and maintenance costs.

In addition, since the equipment itself is not complicated and simple, there is an advantage that it is easy to manage.

FIG. 1A and FIG. 1B are perspective views showing a water purification apparatus to which an intensive aeration is applied according to the present invention. FIG.
FIG. 2A and FIG. 2D are views showing the flow of air and wastewater when the water purifier according to the present invention is operated.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIGS. 1A and 1B are perspective views showing a water purification apparatus to which an intensive aeration is applied according to the present invention. FIGS. 2A and 2D are views showing the flow of air and wastewater when the water purification apparatus using the intensive aeration according to the present invention is operated. .

The water purifier according to the present invention is installed in wastewater stored in a wastewater treatment tank or installed in an enclosed water body such as a reservoir or a lake to purify wastewater or wastewater. The water purifier includes a blower 10, a blower 10 An air inlet pipe 20 connected to the air inlet pipe 20 and an air inlet pipe 30 communicating with the air inlet pipe 20 and a plurality of air inlet ducts 30 communicating with the air outlet pipe 30 below the air outlet shaft 30, An air induction pipe 40, a diffuser 50 installed at a lower end of the air induction pipe 40, a concentrating tube 60 surrounding the air induction pipe 40, And a vapor-liquid pressure axial pipe 80 provided at an upper end of the concentrated wastewater 60. As shown in FIG.

The blower 10 generates a flow of air and strongly blows air in one direction.

The air inlet pipe 20 is connected at one end to the blower 10 to receive air from the blower 10. That is, the air generated from the blower 10 flows into the air inflow pipe 20 and flows.

The air pressure pipe 30 has a general shape similar to a ring shape and is connected to the other end of the air inflow pipe 20 to receive air from the air inflow pipe 20. The air introduced into the air pressure shaft tube 30 gradually compresses while rotating along the inside of the air pressure shaft tube 30.

The air induction pipe 40 is vertically downwardly mounted on the air pressure shaft pipe 30, and a plurality of air induction pipes 40 are installed at a predetermined interval below the air pressure pipe 30. The number of air induction pipes can be increased or decreased in consideration of various situations such as the processing capacity and structural stability of the water purification apparatus.

The air induction pipe (40) is formed such that its inner diameter is smaller than the inner diameter of the air pressure shaft tube (30). Accordingly, the air that has been compressed in the air pressure shaft tube 30 flows strongly downward along the air induction pipe 40.

The diffuser 50 is installed at the lower end of the air induction pipe 40 and flows downward along the air induction pipe 40 to change the air blown out of the air induction pipe 40 into a micropores. In addition, the diffuser 50 is similar to a porous block having a plurality of micropores. When a hole is formed at the center and the lower end of the air induction pipe 40 is inserted into the hole, the air flowing out of the air induction pipe 40 Is dispersed by the micropores of the porous block and is converted into the micropores.

The lower end of the concentration intensive organ 60 touches the bottom surface of the wastewater treatment tank to entirely support the water purification apparatus of the present invention. The central intensifier 60 has an inner diameter larger than the outer diameter of the air induction pipe 40 and the outer diameter of the diffuser 50 to surround the air induction pipe 40 and the diffuser 50.

Since the inner diameter of the concentrating tube 60 is larger than the outer surface of the air induction tube 40, a certain space (gap) is generated between the inner surface of the concentrating tube 60 and the outer surface of the air induction tube 40 I can not help it. The minute bubbles generated by the diffuser 50 through this space are moved upward along the central intensifier 60.

The wastewater inflow pipe (70) is installed so that its both ends are in communication with the concentrated wastewater (60). This wastewater inflow pipe 70 is located in the wastewater because it is installed on the lower side of the concentrated wastewater 60. A plurality of inflow holes 71 are formed in the wastewater inflow pipe 70 so that wastewater is supplied into the wastewater inflow pipe 70 through the inflow holes 71.

The wastewater introduced through the inlet hole 71 flows into the central intensifier 60 through the wastewater inlet pipe 70 and flows along the space between the air induction pipe 40 and the central intensifier 60 And flows upward. At this time, the wastewater is concentrated and aerated by the micro bubbles generated by the diffuser 50. In other words, the air is converted into the micro-bubbles by the diffuser, and the minute bubbles are concentrated in the wastewater and flow upward as the wastewater in the space between the air induction pipe 40 and the central intensifier 60 to help purify the wastewater .

The gas-liquid pressure shaft tube 80 has a general shape similar to a ring shape and has an inner diameter larger than the outer diameter of the air induction pipe 40 and is provided at the upper end of the concentrating tube 60. That is, one of the annular vapor-liquid pressure shaft pipes 80 is connected to the upper end of the plurality of the concentric cylinders 60 to securely fix the upper end of the concentric cylinder 60. The air induction pipe 40 extends through the vapor-liquid pressure shaft tube 80 to the inner space of the concentrating tube 60.

A discharge port 81 is formed in the vapor-liquid pressure shaft tube 80 at regular intervals.

The discharge port 81 is formed along the vapor-liquid pressure shaft tube 80 and formed at an intermediate point between the central intensifier 60 and the central intensifier 60 can further promote the mixing of the micropowder and the wastewater. .

The wastewater that rises along the inside of the central intensifier 60 is concentrated and aerated by the minute bubbles rising together in the ascending process. After the aeration is performed, the wastewater and the fine bubbles continue to rise upward, The air and the wastewater are gradually compressed while being flowed therein, and then sprayed onto the water surface through the discharge port 81. [

On the other hand, the discharge port (81) of the vapor-liquid pressure shaft tube (80) is provided with an extension pipe (82), and the wastewater containing fine bubbles can be jetted to a farther place. Since the extension pipe 82 has a long length, it may be formed in a curved shape by bending a certain point, or may be rounded at a certain curvature.

Hereinafter, the operation of the water purifier according to the present invention will be briefly described.

Air is forcedly blown into the blower 10 to supply air into the air inflow pipe 20.

The air supplied into the air inlet pipe 20 flows into the air pressure shaft pipe 30 and is gradually compressed and then supplied into the air induction pipe 40 to move downward.

The air that has flowed downward along the air induction pipe 40 is dispersed by the diffuser 50 and becomes micro-saturated.

The minute bubbles rise upward along the space between the central intensifying tube 60 and the air induction tube 40. At this time, a rising buoyancy of air acts on the inside of the central intensifying tube 60, The bottom wastewater at the bottom is naturally pumped into the wastewater inflow pipe 70 through the inflow hole 71 and then flows into the intensive wastewater 60 successively.

The deep wastewater flowing into the intensive borehole 60 rises upward along the space between the intensive borehole 60 and the air induction pipe 40 and is concentrated and aerated by the micro bubbles rising together in this process . Then, the organic contaminants of the deep wastewater adhere to the surfaces of the minute bubbles rising along the concentration wick 60.

In this case, the pressure in the concentrated wastewater 60 is increased by the increase of the pressure. As a result, the wastewater in the deep layer becomes denser as the minute bubbles become denser, And then sprayed strongly over the water surface through the discharge port 81 and the extension pipe 82.

In this way, deep wastewater mixed with gas and liquid is strongly sprayed on the water surface, thereby increasing the amount of dissolved oxygen and promoting the growth of aerobic microorganisms, thereby facilitating removal of various contaminants including volatile organic substances.

Through this process, the contaminated wastewater is purified, then circulated back to the deep water, and then supplied again to the surface of the water.

10: blower 20: air inlet pipe
30: air pressure shaft 40: air induction pipe
50: Diffuser 60: Intensive Width
70: Waste water inflow pipe 71: Inflow hole
80: Vapor pressure shaft 81: Outlet
82: extension tube

Claims (3)

An air inlet pipe (20) for receiving air from the blower (10);
An air pressure shaft tube (30) for receiving air from the air inlet tube (20);
A plurality of air induction pipes 40 installed downwardly from the air pressure shaft pipe 30 to flow the air supplied from the air pressure shaft pipe 30 downward;
A diffuser (50) installed at a lower end of the air induction pipe (40) and converting the air flowing downward into a fine particle;
(60) having an inner diameter larger than the outer diameter of the air induction pipe (40) and surrounding the air induction pipe (40) and the diffuser (50);
A wastewater inflow pipe 70 provided at a lower side of the concentrated wastewater 60 and located in the wastewater, and having a plurality of inflow holes 71 through which wastewater flows;
And a gas-liquid pressure shaft tube (80) provided at an upper end of the concentrating tube (60) and having a discharge opening (81) at regular intervals,
The wastewater flowing through the inflow hole 71 flows upward in a space between the air induction pipe 40 and the intensive borehole 60 and is concentratedly aerated by the minute bubbles generated by the diffuser 50 And the water is sprayed onto the water surface through the discharge port (81).
The method according to claim 1,
And an extension pipe (82) is provided at a discharge port (81) of the vapor-liquid pressure shaft pipe (80).
The method of claim 2,
Wherein the extension pipe (82) is bent or rounded at a predetermined curvature.

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