KR20170119950A - An apparatus for advanced waste water treatment and its operational methods - Google Patents

Abstract

The present invention relates to an apparatus for advanced treatment of wastewater and an advanced treatment method for wastewater using the wastewater. More particularly, the present invention relates to an apparatus for advanced treatment of wastewater, To an apparatus for advanced treatment of wastewater that can increase the nitrogen removal efficiency by increasing the flocculation efficiency and an advanced treatment method of wastewater using the wastewater.

Description

[0001] The present invention relates to an apparatus for advanced treatment of wastewater and an advanced treatment method for wastewater using the same,

The present invention relates to an apparatus for advanced treatment of wastewater and a method for treating wastewater using the same. More particularly, the present invention relates to a wastewater treatment apparatus which includes a slope plate settling tank and a membrane separation tank, decompresses the activated sludge, To an apparatus for advanced treatment of wastewater that can increase flocculation efficiency and nitrogen removal efficiency, and a method for advanced treatment of wastewater using the same.

Industrialization and urbanization of mankind greatly increase the emissions of nutrients such as nitrogen and phosphorus, causing eutrophication of coastal and lakes, causing red tides and green tides, severely polluting the water environment. A / O, A2 / O, Bardenpho, VIP, UCT, SBR, MBR, etc., which are processes for removing nitrogen and phosphorus, which are substances that cause eutrophication after secondary treatment for organic matter removal, Various methods have been used.

A / O (Anaerobic / Oxic), A2 / O (anaerobic / anoxic / oxic), and UCT (University of Capetown) can be categorized in various ways depending on the configuration and operation method of the reactor. ), And Bardenpho process, and a side stream process in which anaerobic anaerobic digestion is connected in parallel, such as Phostrip and PL-Ⅱ. In addition, it can be classified into a spatial arrangement type in which the phase of the reaction vessel is fixed and a time arrangement type in which the phase of the reaction vessel changes with time.

Although the above various processes are obviously a process with a relatively high treatment efficiency, although the problems such as sludge expansion, micro flocs and sludge floatation are often caused in the subsequent gravity sedimentation tank due to changes in temperature or operating conditions, , There is a problem that the quality of the treated water deteriorates. In particular, application of a method similar to A2 / O to domestic wastewater with low nutrient concentration compared to nitrogen and phosphorus results in a decrease in denitrification efficiency due to lack of carbon source. As a result, nitrate nitrogen is introduced into the anaerobic tank through the return sludge, Organic competing between the bacteria and the denitrifying microorganisms occurs, resulting in a problem of low emission of phosphorus.

In addition, since the gravitational sedimentation method used in the conventional process described above is difficult to maintain the concentration of the microorganisms in the reaction tank at a certain level or more, the ability to cope with high load is decreased and the limit of maintaining the hydraulic retention time relatively long have. Therefore, membrane-bound bioreactor method (membrane bioreactor method) which combines the biological contaminant removal process and the membrane filtration method which can achieve stable solid-liquid separation using a membrane having a certain nominal pore size instead of the existing solid- -Reactor). MBR is a technology that can almost completely separate and remove oil / inorganic pollutants and microorganisms present in wastewater by using micropore size and membrane surface charge of membrane. The membrane is modular and can be easily combined with other physicochemical or biological treatment devices to form an efficient wastewater treatment device. Generally, it is known that MBR can maintain the concentration of microorganisms in the reaction tank at a high level, thereby enhancing the activity of microorganisms when the influent load is high, and thus has excellent water treatment efficiency, especially nitrogen and phosphorus removal efficiency.

However, due to membrane fouling, which is inevitably generated when the MBR is operated, periodic cleaning and replacement of the membrane is required, which increases operating costs.

In order to solve the problems of the prior art as mentioned above, the present invention solves the problems of the prior art as described above, in which activated sludge is solubilized using air depressurization, and coagulation efficiency is increased using caustic soda and coagulant, And an object of the present invention is to provide an apparatus for advanced treatment of wastewater and an advanced treatment method for wastewater using the same.

According to the present invention,

Deaeration anoxic tank in which wastewater flows;

A plurality of reaction vessels into which waste water treated in the deaerating anoxic tank flows;

A slope plate sedimentation tank connected to the reaction tank; And

A membrane separation tank into which wastewater treated in the slope plate settling tank flows; Containing

An apparatus for advanced treatment of wastewater is provided.

The apparatus for treating wastewater according to the present invention is characterized in that the deaerating anoxic tank and the reaction tank are disposed in contact with each other with a first separator interposed therebetween and the reaction tank and the slope plate settling tank are disposed in contact with each other with the second separator interposed therebetween, And the membrane separation tank is arranged in contact with the third separator interposed therebetween.

In the apparatus for treating wastewater according to the present invention, the first separator includes a first through-hole opened at the lower portion, and the second separator includes a second through-hole opened at the lower portion.

In the wastewater treatment apparatus according to the present invention, the deaeration anoxic tank may include an agitator formed at a position lower than the first through-hole height.

In the wastewater treatment apparatus according to the present invention, the third separator disposed between the swash plate settling tank and the membrane separating tank may include a weir which is disposed lower than the water surface of the wastewater so that the wastewater of the swash plate settling tank can flow .

The apparatus for advanced treatment of wastewater according to the present invention is characterized in that it comprises first conveying means for conveying the slurry of the inclined plate precipitation tank to the reaction tank.

The wastewater treatment apparatus according to the present invention is characterized in that it comprises second conveying means for conveying the active slurry of the membrane separation tank to the above-mentioned deaeration anoxic tank.

In the apparatus for treating wastewater according to the present invention, the first conveying means is connected to an active slurry receiving portion for containing an active slurry.

In the apparatus for treating wastewater according to the present invention, the active slurry receiving portion is connected to caustic soda and a flocculant storage portion.

The present invention also relates to

Introducing the wastewater into the degassing anoxic tank;

Flowing the wastewater from the deaerating anoxic tank into the reaction tank;

Flowing wastewater from the reaction tank into a slope plate settling tank; And

And introducing wastewater from the slope plate settling tank into the membrane separation tank

A method for advanced treatment of wastewater using a wastewater treatment apparatus according to claim 1 is provided.

The method for advanced treatment of wastewater according to the present invention is characterized by further comprising the step of returning activated sludge of the slope plate settling tank to the reaction tank.

The method for treating wastewater according to the present invention comprises the steps of: transporting activated sludge of the membrane separation tank to an anaerobic degassing step; And further comprising:

In the method for treating wastewater according to the present invention, in the step of conveying the activated sludge of the slope plate settling tank to the reaction tank, the step of solubilizing the activated sludge of the slope plate settling tank is solved.

In the method for advanced treatment of wastewater according to the present invention, in the step of solubilizing the activated sludge, the active slurry containing portion containing the activated sludge is decompressed to be solubilized.

In the method for treating wastewater according to the present invention, in the step of solubilizing the activated sludge, caustic soda and coagulant are injected into the active slurry.

The apparatus for advanced treatment of wastewater according to the present invention is characterized in that the activated sludge is supplied to the upper part of the reaction tank and the wastewater flows into and out from the lower part of the reaction tank, Can be solubilized and supplied to the reaction tank, whereby nitrogen can be removed more efficiently. At this time, in the solubilization process, the activated sludge can be depressurized using air, and caustic soda and coagulant can be injected to improve coagulation efficiency, thereby more effectively removing nitrogen.

In addition, since the activated sludge of the membrane separation tank is also transported to the degassing anoxic tank, the nitrogen removal efficiency can be further improved.

1 is a block diagram showing an apparatus for advanced treatment of wastewater according to an embodiment of the present invention.
2 is a schematic plan view for explaining the arrangement of each set installed in an apparatus for advanced treatment of wastewater according to an embodiment of the present invention.
3 is a schematic cross-sectional view for explaining the height of each tank installed in the apparatus for advanced treatment of wastewater according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. However, the present invention is not limited to the following figures and examples.

FIG. 1 is a block diagram showing an apparatus for advanced treatment of wastewater according to an embodiment of the present invention. FIG. 2 is a schematic plan view for explaining the arrangement of each set installed in an apparatus for advanced wastewater treatment according to an embodiment of the present invention. to be.

As shown in FIG. 1 and FIG. 2, the apparatus for advanced treatment of wastewater according to the present invention includes a deaeration anoxic tank 10 into which wastewater flows and an impeller 14 is formed at a lower portion thereof; A plurality of reaction vessels 20a and 20b connected to the degassing and anoxic tank 10 to which wastewater treated in the degassing anoxic tank 10 flows; A slope plate settling tank 30 connected to the plurality of reaction tanks 20a and 20b to receive wastewater treated in the plurality of reaction tanks; A membrane separation tank (40) having a weir (42) installed lower than the water surface of the wastewater so that the wastewater of the swash plate settling tank (30) can flow; First conveying means for conveying the sludge of the inclined plate sedimentation tank (30) to the plurality of reaction vessels (20a, 20b); And a second conveying means for conveying the sludge of the membrane separation tank (40) to the deaeration anoxic tank (10).

1, the apparatus for advanced treatment of wastewater according to the present invention is characterized in that the degassing anoxic tank 10, the reaction vessels 20a and 20b, the slope plate settling tank 30 and the membrane separation tank 40 are separated from each other 2, the deaeration anoxic tank 10 is disposed in contact with the reaction vessels 20a, 20b and the first separation unit 11, and the reaction vessels 20a, The slope plate settling tank 30 and the membrane separation tank 40 are packaged in a single unit so as to be in contact with each other with the third separator interposed therebetween, .

FIG. 3 is a cross-sectional view illustrating a connection state and an operation procedure of each group when the apparatus for advanced treatment of wastewater according to an embodiment of the present invention is packaged in one unit as shown in FIG.

3, the deaeration anoxic tank 10 is disposed in contact with the reaction vessels 20a and 20b and the first separation unit 11 with the bottom of the first separation unit 11 being open, One through-hole 12 is formed, and an agitator 13 is provided in a direction perpendicular to the center. The impeller 14 of the stirrer 13 is installed in the first through hole 12 and is connected to the deaerating anoxic tank 10 and the deaerating anoxic tank 10 through the first through hole 12 by stirring action by the impeller, The flow of the wastewater between the reactors 20a and 20b formed around the reactor 10 is induced. That is, when the impeller is rotated, the wastewater is radially discharged, so that after the wastewater flowing into the upper portion of the deaerating anoxic tank 10 is deaerated, the lower portion of the first separator 11 is opened, And is supplied to the plurality of reaction vessels 20a and 20b through the first through-hole 11 in the lower part because it moves in the radial direction by the operation of the lower impeller 14 formed at a lower position than the sphere 12. [

The reaction vessels 20a and 20b are preferably provided as a plurality of reaction vessels 20a and 20b disposed around the degassing anoxic tank 10 to further activate the reaction.

The reaction vessels 20a and 20b are disposed adjacent to each other with the swash plate settling tank 30 and the second separation unit 21 interposed therebetween and the lower part of the second separation unit 21 is provided with an open second through- The wastewater flows between the reaction vessels 20a and 20b and the swash plate settling tank 30 through the second through-hole 22. [

The swash plate settling tank 30 has a swash plate 32 laminated therein so that the sedimentation efficiency is high and the concentration of the activated sludge can be maintained at a high concentration even if there is no separate mixing power in the swash plate settling tank 30. As a result, the activated sludge concentration of the membrane separation tank 40 to which the wastewater treated in the slope plate settling tank is supplied can be kept low due to the settling property of the slope plate settling tank 30, so that the flux and acid energy can be reduced.

When the bubbles are generated due to the dropping of the wastewater flowing into the swash plate settling tank 30, the oxygen may flow into the wastewater due to the dropping of the wastewater flowing thereinto. In this case, A swash plate is installed to remove air bubbles. The introduced wastewater does not directly fall into the swash plate settling tank 30 but flows along the sidewall surface in the swash plate, thereby preventing the generation of bubbles due to the fall.

The activated sludge of the slope plate settling tank 30 is supplied to the reaction vessels 20a and 20b through the first conveying means 33 connected to the upper side of the slope plate settling tank 30. The first conveying means solubilizes the high concentration activated sludge of the slope plate settling tank (30) and supplies it to the reaction vessels (20a, 20b).

In addition, the first transporting means can supply activated sludge of the slope plate settling tank 30 to the deaeration anoxic tank 10, if necessary.

Activated sludge of the slope plate settling tank 30 is solubilized and activated at a high concentration in the process of supplying the activated sludge of the slope plate settling tank 30 to the deaeration anoxic tank 10 and then supplied to the reaction tanks 20a and 20b.

The slope plate settling tank 30 and the membrane separation tank 40 are disposed to be in contact with each other with the third separation unit 41 therebetween and a membrane separator 44 is installed in the membrane separation tank 40. The third separator 41 formed between the slope plate settling tank 30 and the membrane separation tank 40 is provided with a weir which is lower than the water surface to allow the wastewater treated in the slope plate settling tank 30 to flow, 42).

The second transfer means (43) supplies the activated sludge of the membrane separation tank (40) to the degassing anoxic tank (10).

The present invention also relates to

Introducing the wastewater into the degassing anoxic tank;

Flowing the wastewater from the deaerating anoxic tank into the reaction tank;

Flowing wastewater from the reaction tank into a slope plate settling tank; And

And a step of introducing wastewater from the swash plate settling tank into the membrane separation tank. The present invention also provides a method for advanced treatment of wastewater using the apparatus for advanced treatment of wastewater.

Preferably, the method for treating wastewater according to the present invention further comprises the step of returning the activated sludge of the slope plate settling tank to the reaction tank.

The method for treating wastewater according to the present invention comprises the steps of: transporting activated sludge of the membrane separation tank to an anaerobic degassing step; . The deaerating anoxic tank 10 is connected to the membrane separation tank 40 through the second conveying means and is supplied with sludge and can receive the activated sludge from the slope plate settling tank 30 as required.

In the method for treating wastewater according to the present invention, in the step of transporting the activated sludge of the slope plate settling tank to the reaction tank, a step of solubilizing the activated sludge by reducing the pressure of the activated sludge in order to solubilize the activated sludge of the slope plate settling tank .

In the method for treating wastewater according to the present invention, the activated sludge of the slope plate settling tank 30 is conveyed to the upper portion of the slope plate settling tank 30 33 to the reaction vessels 20a, 20b. At this time, it is preferable that the activated sludge of the swash plate settling tank 30 is supplied by being solubilized.

The activated sludge conveyed to the reaction vessels 20a and 20b is preferably supplied with caustic soda (NaOH) and a coagulant. It is possible to separately provide the caustic soda reservoir for supplying the caustic soda and the flocculant reservoir 24 or 26 for supplying the flocculant. Through the solubilization of the activated sludge, cavitation phenomenon occurs, and activated sludge becomes enthalized and hydrolyzed by caustic soda, thereby generating an organic carbon source necessary for denitrification. In addition, coagulant injected with caustic soda improves the flocculation efficiency of phosphorus.

In addition, the solubilized activated sludge supplied from the slope plate settling tank 30 functions as an anoxic tank in the middle area between the upper part and the lower part while being precipitated, and the denitrification is promoted by the solubilized sludge. Therefore, the reaction vessels 20a and 20b are subjected to three reactions at the same time due to different conditions of the upper, lower and middle conditions.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

10: Deaerating anoxic tank 11: First through hole
12: Stirrer 14: Impeller
20a, 20b: reaction tank 22: second through hole
24: caustic soda tank 26: flocculant tank
30: swash plate settling tank 32: swash plate
40: membrane separation tank 42: weir
44: membrane separator

Claims (15)

Deaeration anoxic tank in which wastewater flows;
A plurality of reaction vessels into which waste water treated in the deaerating anoxic tank flows;
A slope plate sedimentation tank connected to the reaction tank; And
A membrane separation tank into which wastewater treated in the slope plate settling tank flows; Containing
Advanced apparatus for wastewater treatment.
The method according to claim 1,
Wherein the deaeration anoxic tank and the reaction tank are disposed in contact with each other with the first separator interposed therebetween,
The reaction tank and the slope plate settling tank are disposed in contact with each other with the second separator interposed therebetween,
And the slope plate settling tank and the membrane separation tank are disposed in contact with each other with the third separator interposed therebetween
Advanced apparatus for wastewater treatment.
3. The method of claim 2,
Wherein the first separator includes a first through hole opened at a lower portion thereof and the second separator includes a second through hole opened at a lower portion thereof,
Advanced apparatus for wastewater treatment.
The method according to claim 1,
Wherein the degassing anoxic tank includes an agitator formed at a position lower than the first through-hole height
Advanced apparatus for wastewater treatment.
The method according to claim 1,
And the third separator disposed between the swash plate settling tank and the membrane separation tank includes a lower portion provided below the water surface of the wastewater so that the wastewater of the swash plate settling tank can flow.
Advanced apparatus for wastewater treatment.
The method according to claim 1,
And first conveying means for conveying the slurry of the slope plate settling tank to the reaction tank
Advanced apparatus for wastewater treatment.
The method according to claim 1,
And a second transporting means for transporting the active slurry of the membrane separation tank to the deaeration anoxic tank
Advanced apparatus for wastewater treatment.
The method according to claim 6,
And the first conveying means is connected to the active slurry receiving portion for containing the active slurry
Advanced apparatus for wastewater treatment.
9. The method of claim 8,
Wherein the active slurry receiving portion is connected to the caustic soda and the flocculant storage portion
Advanced apparatus for wastewater treatment.
Introducing the wastewater into the degassing anoxic tank;
Flowing the wastewater from the deaerating anoxic tank into the reaction tank;
Flowing wastewater from the reaction tank into a slope plate settling tank; And
And introducing wastewater from the slope plate settling tank into the membrane separation tank
A method for advanced treatment of wastewater using the apparatus for treating wastewater according to claim 1.
11. The method of claim 10,
And returning the activated sludge of the swash plate sedimentation tank to the reaction tank.
A method for advanced treatment of wastewater using a wastewater treatment system.
11. The method of claim 10,
Transporting the activated sludge of the membrane separation tank to an anaerobic degassing step; Lt; RTI ID = 0.0 >
A method for advanced treatment of wastewater using a wastewater treatment system.
12. The method of claim 11,
And the step of transporting the activated sludge of the slope plate settling tank to the reaction tank includes a step of solubilizing the activated sludge of the slope plate settling tank
Advanced treatment of wastewater.
14. The method of claim 13,
In the step of solubilizing the activated sludge, the active slurry containing portion containing the activated sludge is reduced in pressure to be solubilized
Advanced treatment of wastewater.
15. The method of claim 14,
In the step of solubilizing the activated sludge, caustic soda and flocculant are injected into the active slurry
Advanced treatment of wastewater.

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