KR102315900B1 - A2O and SBR hybrid type Wastewater treatment system - Google Patents

Abstract

The present invention relates to an A2O and SBR hybrid wastewater treatment system, and more specifically, to improve wastewater treatment efficiency by effectively reconfiguring the configuration having a stirring function in the first and second reaction tanks in the main treatment process, and in the pretreatment process It relates to an A2O and SBR hybrid wastewater treatment system that removes contaminants and improves the sterilization effect by configuring a post-treatment process using a UV lamp to sterilize the treated water after the main treatment process.
That is, the present invention relates to a pretreatment process in which wastewater is first introduced and a screen for removing contaminants is installed, a main treatment process in which phosphorus and nitrogen are removed and sludge is discharged by receiving wastewater from the pretreatment process, and discharge from the main treatment process It consists of a post-treatment process in which the treated water to be treated is stored in a UV treatment water tank and then subjected to UV sterilization through a UV disinfection device, wherein the main treatment process is; An aeration tank that continuously aerates wastewater in an aerobic state by means of an aeration device, an immersion-type concentration tank that is installed in the aeration tank and continuously sediments and concentrates sewage sludge overflowing inside the aeration tank in anoxic condition and then discharges it with a pump; A dephosphorization tank for overflowing the phosphorus-released wastewater by stirring in an anaerobic state into the discharge hopper part installed on the upper part, a first wall is formed on one side of the aeration tank in the width direction, and a second wall is formed on one side of the first wall in the longitudinal direction A wall is formed and the first and second reaction tanks are formed on both sides based on the second wall, and a flow pipe connected to the discharge hopper of the dephosphorization tank and distributed to the lower portions of the first and second reaction tanks, respectively; , A micro-bubble stirrer is installed at the bottom of the first and second reaction tanks to generate micro-bubbles and a rotational water flow to achieve stirring.

Description

A2O and SBR hybrid type Wastewater treatment system

The present invention relates to an A2O and SBR hybrid wastewater treatment system, and more specifically, to improve wastewater treatment efficiency by effectively reconfiguring the configuration having a stirring function in the first and second reaction tanks in the main treatment process, and in the pretreatment process It relates to an A2O and SBR hybrid wastewater treatment system that removes contaminants and improves the sterilization effect by configuring a post-treatment process using a UV lamp to sterilize the treated water after the main treatment process.

In general, wastewater treatment is treated by various methods, but among them, the Anaerobic-Anoxic-Oxic method is a technology that complements the existing AO method, which was impossible to remove nitrogen. It corresponds to the method of making it go through the process

That is, in the A2O method, sewage and sewage flowing into the anaerobic tank, anoxic tank, and aeration tank release phosphorus from the anaerobic reaction tank and move to the anaerobic tank. Then, ammonia nitrogen in the influent flowing into the aeration tank through the anaerobic tank is oxidized to nitrite and nitrate by active microorganisms under aerobic conditions, and organic matter is removed at the same time. The oxidized nitrogen component is transferred to an anoxic tank through internal transport, is reduced to nitrogen gas under anoxic conditions, and released and removed into the atmosphere. In particular, the phosphate ions released from the anaerobic tank are removed from microorganisms under aerobic conditions.

Among other wastewater treatment methods, the SBR method (Sequencing Batch Reactor) is a method in which sewage inflow, reaction, precipitation, discharge, and resting processes are continuously carried out over time in a single reactor. It is a method of biologically removing organic matter, nitrogen and phosphorus in sewage using microorganisms in anaerobic and anaerobic conditions.

If sewage from which nitrogen and phosphorus has not been removed flows into a river, red tide or green algae may occur due to eutrophication of the river, reducing the amount of dissolved oxygen in the river and destroying the underwater ecosystem. may contaminate In order to solve this problem, various advanced treatment methods for sewage that can remove nitrogen and phosphorus as well as organic matter in the sewage treatment process have been proposed.

Such a wastewater treatment device is more needed not only in Korea but also in developing countries (Vietnam, Thailand, Laos, Cambodia, etc.). The problem of water pollution, a chronic environmental problem that occurs in most developing countries, is a lack of awareness of the water quality environment and water treatment that neglects serious pollution of sewage and rivers while urban population expands and industrial facilities are created due to rapid economic development. This is due to the low level of technology involved.

In particular, Vietnam has recently undergone rapid industrialization and urbanization with an average annual economic growth of 7% (consumption of 65% of GDP). Only half of the country (7.5 million people) are receiving water for daily use through water pipes, so the natural water purification capacity of the water system is declining and water pollution is serious due to urbanization and industrialization.

Republic of Korea Patent Registration 10-1634292 Republic of Korea Patent Registration 10-1229011 Republic of Korea Patent Registration 10-1634296 Republic of Korea Patent Registration 10-1130542

The present invention uses microorganisms in anaerobic, aerobic and anaerobic conditions to biologically remove organic matter, nitrogen and phosphorus in sewage, but the composition of the stirring device installed inside the first and second reaction tanks is of the stirring blades To provide an A2O and SBR hybrid wastewater treatment system that can increase stirring efficiency and purification efficiency by configuring a microbubble stirrer that produces stirring and oxygen supply by microbubbles and strong rotational water flow without stirring through rotation. There is a purpose.

In addition, the present invention filters contaminants contained in wastewater by subjecting it to a pretreatment process including a screen device before going through the main treatment process, and the wastewater discharged from the main treatment process is further subjected to a post-treatment sterilization process using a UV lamp. Another object of the present invention is to provide an A2O and SBR hybrid wastewater treatment system to prevent secondary infection by various bacteria while enabling eco-friendly wastewater treatment.

The present invention relates to a pretreatment process in which wastewater is first introduced and a screen for removing contaminants is installed; It consists of a post-treatment process in which water is stored in a UV treatment water tank and then UV sterilized through a UV disinfection device, the main treatment process being; An aeration tank that continuously aerates wastewater in an aerobic state by means of an aeration device, an immersion-type concentration tank that is installed in the aeration tank and continuously sediments and concentrates sewage sludge overflowing inside the aeration tank in anoxic condition and then discharges it with a pump; A dephosphorization tank for overflowing the phosphorus-released wastewater by stirring in an anaerobic state into the discharge hopper part installed on the upper part, a first wall is formed on one side of the aeration tank in the width direction, and a second wall is formed on one side of the first wall in the longitudinal direction A wall is formed and the first and second reaction tanks are formed on both sides based on the second wall, and a flow pipe connected to the discharge hopper of the dephosphorization tank and distributed to the lower portions of the first and second reaction tanks, respectively; , A micro-bubble stirrer is installed at the bottom of the first and second reaction tanks to generate micro-bubbles and a rotating water flow to achieve stirring.

The present invention constitutes a microbubble stirrer in which the stirring device installed inside the first reaction tank and the second reaction tank does not have a stirring action through the rotation of the stirring blades, and the stirring and oxygen supply are made by microbubbles and strong rotational water flow. Thus, there is an effect of increasing the stirring efficiency and the purification efficiency.

In addition, the present invention has an effect of filtering contaminants contained in wastewater by subjecting it to a pretreatment process including a screen device before going through the main treatment process, and the wastewater discharged from the main treatment process is post-treatment sterilization using a UV lamp again By further processing, there is an effect of eco-friendly wastewater treatment and prevention of secondary infection caused by various bacteria.

1 is a block diagram showing the A2O and SBR hybrid wastewater treatment system of the present invention
2 is a view showing the main processing process of the present invention;
3 is a plan view showing the main processing process of the present invention;
4 is a view showing a post-treatment process of the present invention;
5 is a view showing a UV disinfection device in the post-treatment process of the present invention;
6 is a side cross-sectional view showing the internal configuration of the UV disinfection device in the post-treatment process of the present invention;
7 is an enlarged cross-sectional view of the main configuration of the UV disinfection device in the post-treatment process of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The A2O and SBR hybrid wastewater treatment system of the present invention supplies wastewater in the pretreatment process (A) in which wastewater is first introduced and a screen for removing contaminants is installed, as shown in FIG. 1, and in the pretreatment process (A) The main treatment process (B) in which phosphorus and nitrogen are removed and sludge is discharged, and the treated water discharged from the main treatment process (B) is stored in a UV treatment water tank, and then goes through a UV disinfection device for UV sterilization. It has a structure which consists of a process (C).

The pretreatment process (A) is configured such that wastewater is first introduced and contaminants having a large size of foreign substances are selectively removed by a screen. In the pretreatment process (A), at least one screen is installed, and wastewater filtered by the screen is supplied to the main treatment process (B).

The main treatment process (B) of the present invention is a configuration in which wastewater is supplied, nitrogen and phosphorus, which are the sources of water pollution, is removed, and sludge generated in the treatment process is discharged, and the specific configuration is as shown in FIGS. Likewise, the aeration tank 100 for continuously aeration of wastewater in an aerobic state by the aeration device 110, and the aeration tank 100 installed in the aeration tank 100 to continuously sediment and concentrate the sludge of sewage overflowing into the inside in an anaerobic state, and then discharge it with a pump The immersion type concentration tank 200, the raw water and the sludge discharged from the submersion type concentration tank 200 are returned to the bottom and stirred in an anaerobic state to overflow the phosphorus-released wastewater into the discharge hopper unit 510 installed on the upper part. A first wall 410 is formed on one side of the artificial body 300 and the aeration tank 100 in the width direction, and a second wall 420 is formed on one side of the first wall 410 in the longitudinal direction. The first reaction tank 400a and the second reaction tank 400b are formed on both sides with respect to the wall 420, and the first reaction tank 400a and the second reaction tank 400b are connected to the discharge hopper part 510 of the dephosphorization tank 300. A flow path pipe 500 distributed and installed to the lower part of the second reaction tank 400b, and microbubbles and rotational water flow are generated in the bottom of the first reaction tank 400a and the second reaction tank 400b so that agitation is performed. Bubble stirrer 600; characterized in that it is installed.

In the main treatment process (B) of the present invention, the inside is partitioned into three zones by the first wall 410 and the second wall 420 , and the part partitioned in the width direction by the first wall 410 . corresponds to the aeration tank 100 , and a first reaction tank 400a and a second reaction tank 400b partitioned by a second wall 420 are formed side by side on one side of the aeration tank 100 .

An opening 430 communicating with the first reaction tank 400a and the second reaction tank 400b is formed in the first wall 410, and the wastewater of the first reaction tank 400a or the second reaction tank 400b is an aeration tank. It corresponds to the passage through which the wastewater moves to ( 100 ) or the aeration tank ( 100 ) moves to the first reaction tank ( 400a ) or the second reaction tank ( 400b ). In this case, when the opening 430 is formed at the lower end of the first wall 410 , the movement of wastewater is made downward, thereby reducing the occurrence of odors.

The aeration tank 100 is a part that maintains an aerobic state by activating the aerobic microorganisms contained in the wastewater to continuously aerate oxygen to help decompose organic matter, the nitrification process of the wastewater, and the phosphorus absorption of the dephosphorization microorganisms. An aeration device 110 is installed.

And the submerged type concentration tank 200 is installed on one side of the inside of the aeration tank 100, and the wastewater overflowed along the inner wall of the aeration tank 100 flows in, so that the sludge of the wastewater is continuously precipitated by gravity, so that the sludge discharge pump (not shown) is discharged to the outside. Since the submerged concentration tank 200 is blocked from the aeration tank 100 and the aerobic environment, the sludge is deposited while maintaining an anaerobic state.

In the dephosphorization tank 300, raw water corresponding to wastewater to be treated is first introduced, and phosphorus is released as the stirring device 310 installed in the dephosphorization tank 300 operates under anaerobic conditions. And an upwardly opened discharge hopper part 510 is formed on the inner upper part of the dephosphorization tank 300 so that the phosphorus-removed wastewater is overflowed to the upper part of the discharge hopper part 510 .

The flow pipe 500 is configured such that the dephosphorized wastewater in the dephosphorization tank 300 is supplied to the first reaction tank 400a and the second reaction tank 400b through the discharge hopper unit 510 .

The microbubble agitator 600 of the present invention is installed at the bottom of the first reaction tank 400a and the second reaction tank 400b to generate a rotational water flow along with the generation of microbubbles so as to be stirred. In this way, when agitation is achieved by generating microbubbles and forced water flow without applying a physical agitation configuration such as agitation blades, stirring is facilitated by the synergistic action of microbubbles, and oxygen in microbubbles is delivered to improve purification efficiency. have the advantage of increasing it.

The microbubble agitator 600 includes a microbubble generating unit 610 for generating microbubbles by mixing external air and wastewater introduced by the rotational force of an impeller mounted therein, and the microbubble generating unit 610. Fluid provided by is formed at each end of the distribution pipe 620 and the distribution pipe 620 to discharge the microbubbles.

4 is a view showing the post-treatment process (C) of the present invention, more preferably first sterilized through the UV pre-treatment lamp 711 installed in the UV treatment water tank 710, and then sent to the UV disinfection device 720 It is composed of secondary sterilization. At this time, the UV pretreatment lamp 711 installed in the UV treatment water tank 710 and the UV lamp 723 installed in the UV disinfection device 720 are preferably adjusted to different UV wavelengths or outputs to expand the sterilization range.

The UV disinfection device 720 has a cylindrical shape as shown in FIGS. 5 to 6 , an inlet 721-1 to which wastewater corresponding to a disinfection target is supplied, and an exhaust for discharging sterilized purified water. A body portion 721 in which the portion 721-2 is formed, a chemical supply portion 722 formed in the main body portion 721 to supply chemicals necessary for sterilization, and a length in the center of the main body portion 721 A UV lamp 723 installed horizontally in the direction, ^{a bubble generating unit 724 installed under the UV lamp 723 to generate ozone (O 3} ) bubbles, and the UV lamp 723 installed on the upper portion and a blocking plate 725 such that the bubbles rising from the bubble generating unit 724 stay around the UV lamp 723; characterized in that it is composed of.

The body part 721 has an inlet part 721-1 and an outlet part 721-2 formed at the upper part, so that wastewater is filled in the body part 721 through the inlet part 721-1 and sterilized. The purified water is discharged to the outside through the discharge unit 721-2. And on one side of the main body portion 721 is formed a chemical supply portion 722 to which the medicine necessary for sterilization is supplied. In this case, the chemical supply unit 722 may supply a chemical necessary for oxidation treatment, and hydrogen peroxide may be injected as an example.

The conventional UV sterilization method is installed on the cover of the water tank and irradiating UV rays with water filled in the water tank.

Therefore, the UV lamp 723 of the present invention is installed in the center horizontally in the longitudinal direction of the main body 721, so that the UV lamp 723 is submerged in wastewater. Therefore, the ultraviolet rays generated from the UV lamp 723 are transferred to the wastewater in the 370° direction, thereby further increasing the sterilization efficiency. The UV lamp 723 may be inserted as it is, but it is preferable to further configure a transparent cover 723a outside the UV lamp 723 to prevent the lamp replacement problem and contact with wastewater.

The bubble generating part 724 is installed under the UV lamp 723 ^{to generate ozone (O 3} ) bubbles, and a through part 724-1 through which the bubbles are discharged is formed. A preferred embodiment of the bubble generating unit 724 is that as shown in FIG. 7, a plurality of UV lamps 723 are arranged at a certain radius on the arc. That is, ozone (O ³ ) bubbles are generated around the UV lamp 723 to improve the synergy between the sterilization effect of ozone and the sterilization effect of the UV lamp 723 , and the generated bubbles collide with the UV lamp 723 . It promotes the generation of bubbles and increases the residence time so that the sterilization effect is continued.

And the blocking plate 725 is installed on the upper portion of the UV lamp 723 so that the bubbles rising from the bubble generating unit 724 stay around the UV lamp 723 . That is, the sterilization effect is further enhanced by inducing the ozone bubbles to remain in the wastewater without rising immediately. The preferred shape of the blocking plate 725 is preferably developed in a semicircular arc shape centered on the UV lamp 723 as shown in the drawings.

In addition, when the reflective layer 725-1 is coated on the inside of the blocking plate 725, the ultraviolet rays generated from the UV lamp 723 are reflected by the reflective layer 725-1 and irradiated to the lower side, thereby sterilizing effect. can be further increased.

An air exhaust hole 725 - 2 is formed in the center of the blocking plate 725 to prevent an air layer from being formed inside the blocking plate 725 . A plurality of the air discharge holes 725 - 2 may be formed in the longitudinal direction of the blocking plate 725 .

As such, the UV disinfection device 720 of the present invention is sterilized through the UV lamp 723 and ozone (O ³ ) bubbles, so that the chemical cost due to chlorine disinfection used in the existing disinfection device can be greatly reduced, There is an advantage in that the disinfection effect including chlorine-resistant microorganisms is maximized.

Although the present invention has been described above with reference to the above embodiments, it goes without saying that various modifications are possible within the scope of the technical spirit of the present invention.

A: Pretreatment process B: Main treatment process
C: Post-treatment process
100: aeration tank 110: aeration device
200: immersion type concentration tank 300: de-humanization tank
310: stirring device 400a: first reaction tank
400b: second reaction tank 410: first wall
420: second wall 430: opening
440: opening and closing door 441: rotation shaft
442: gear 500: flow pipe
510: discharge hopper 600: micro-bubble agitator
610: microbubble generating unit 620: distribution pipe
630: fine bubble nozzle unit
710: UV treatment tank 711: UV pretreatment lamp
720: UV disinfection device 721: body part
721-1: inlet 721-2: outlet
722: chemical supply unit 723: UV lamp
723a: transparent cover 724: bubble generating part
724-1: through part 725: blocking plate
725-1: Reflective layer 725-2: Air exhaust hole

Claims (6)

A pretreatment process in which wastewater is first introduced and a screen is installed to remove contaminants, a main treatment process in which phosphorus and nitrogen are removed and sludge is discharged by receiving wastewater from the pretreatment process, and the treated water discharged from the main treatment process is UV treated It is stored in a treatment water tank and then goes through a UV sterilization device for UV sterilization, which is a post-treatment process.
The main treatment process is; An aeration tank that continuously aerates wastewater in an aerobic state by means of an aeration device, an immersion-type concentration tank that is installed in the aeration tank and continuously sediments and concentrates sewage sludge overflowing inside the aeration tank in anoxic condition and then discharges it with a pump; A dephosphorization tank for overflowing the phosphorus-released wastewater by stirring in an anaerobic state into the discharge hopper part installed on the upper part, a first wall is formed on one side of the aeration tank in the width direction, and a second wall is formed on one side of the first wall in the longitudinal direction A wall is formed and the first and second reaction tanks are formed on both sides based on the second wall, and a flow pipe connected to the discharge hopper of the dephosphorization tank and distributed to the lower portions of the first and second reaction tanks, respectively; , A micro-bubble stirrer is installed at the bottom of the first and second reaction tanks to generate micro-bubbles and a rotational water flow so that agitation is achieved,
The post-treatment process consists of a process of primary sterilization through a UV pre-treatment lamp installed in a UV treatment tank, and then sent to a UV disinfection device for secondary sterilization,
UV disinfection device of the post-treatment process;
A main body portion formed in a cylindrical shape and having an inlet to which wastewater corresponding to a disinfection target is supplied and an outlet for discharging sterilized purified water;
a drug supply unit formed in the main body to supply drugs necessary for sterilization;
A UV lamp installed horizontally in the longitudinal direction in the center of the main body,
a bubble generating unit installed under the UV lamp to generate ozone (O3) bubbles;
a blocking plate installed on the upper part of the UV lamp so that the bubbles rising from the bubble generating unit stay around the UV lamp; and
A plurality of the bubble generating units are arranged in a predetermined radius on the arc of the UV lamp, and the blocking plate is formed in a semicircular arc shape around the UV lamp,
A reflective layer is coated on the inside of the blocking plate so that the ultraviolet rays generated from the UV lamp are reflected by the reflective layer and irradiated to the lower side to increase the sterilization effect.
The bubble generating part is arranged in plurality at the lower part with a certain radius on the arc of the UV lamp,
The A2O and SBR hybrid type wastewater treatment system, characterized in that the blocking plate is formed in the upper part in the shape of a semi-circular arc centered on the UV lamp.
The method of claim 1,
A2O and SBR hybrid, characterized in that an opening communicating with the first reaction tank and the second reaction tank is formed on the first wall of the main treatment process, respectively, and the opening is formed at the lower end of the first wall to move wastewater to the lower part type wastewater treatment system.
The method of claim 1,
The microbubble agitator of the main treatment process; A micro-bubble generating unit for generating micro-bubbles by mixing external air and wastewater introduced by the rotational force of the impeller mounted therein, a distribution pipe for guiding the fluid provided from the micro-bubble generating unit to various paths, and the distribution pipe A2O and SBR hybrid type wastewater treatment system, characterized in that it consists of; microbubble nozzle unit formed at each end to discharge microbubbles.



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