KR20180049880A - Energy saving Wastewater treatment system using high concentrations dissolved oxygen water - Google Patents

Abstract

A sewage treatment system is provided. The sewage treatment system can reduce power costs and the area of a construction site by supplying oxygen needed for aerobic microorganisms to an aerobic digestion tank in a form that is dissolved in wastewater at a high concentration instead of a bubble form. In addition, since the aerobic digestion tank suppresses the supply of oxygen bubbles and supplies high concentration dissolved oxygen water, energy can be saved and the aerobic digestion tank can be prevented from generating floating sludge, thereby effectively maintaining the aerobic microorganism activity.

Description

Energy - saving sewage and ozone using high concentration dissolved oxygen water. [0001] The present invention relates to a wastewater treatment system,

The present invention relates to sewage and cement. More particularly, to an energy-saving sewage treatment system that efficiently supplies sufficient oxygen by using micro-bubbles required for aerobic microorganisms to remove organic matter.

Generally, in sewage treatment plants, anaerobic digester and anaerobic digester using anaerobic microorganisms and aerobic microorganisms are sequentially treated to treat biological wastewater. Because aerobic microorganisms in aerobic digesters require oxygen, large-capacity blowers and air diffusers are installed under aerobic digesters to blow air.

However, such an aerobic digestion tank requires a large-capacity blower and an air diffuser to blow air, and thus requires a considerably large power cost and requires a large area of the construction site.

In order to solve this problem, it has been proposed to supply oxygen to the micropores produced by using a microbubble device. However, the aerobic digestion tank may cause aerobic microorganisms to die by floating the organic matter (active sludge) together with the floating material due to the high force of the microbubble. Further, the microbubble nozzles of the microbubble device are often clogged, which makes it difficult to operate the aerobic digester, resulting in increased management and economic losses.

Accordingly, an object of the present invention is to provide a sewage treatment system that efficiently supplies oxygen required by aerobic microorganisms without causing suspended matter in a space where aerobic microorganisms remove organic matter.

According to an aspect of the present invention, there is provided a sewage treatment system comprising: a biological treatment tank to which oxygen is supplied; An oxygen mixer including an oxygen generator for drawing out the treated sewage treated in the biological treatment tank and mixing the treated sewage with oxygen generated by the oxygen generator; And a supply pump for supplying treated sewage mixed with oxygen from the oxygen mixer to the biological treatment tank. As a result, the fine bubbles are dissolved in the treated sewage, and the dissolved oxygen can be supplied at a high concentration without supplying the fine bubbles to the aerobic digestion tank.

Here, the bubbler further includes a bubble grinder for crushing oxygen bubbles mixed in the treated sewage in the oxygen mixer, wherein the bubble grinder includes: a rotating crusher for crushing oxygen bubbles contained in the treated wastewater; And a first motor for rotating the rotary crushing unit. Whereby oxygen is apt to dissolve in the sewage.

The bubble eliminator further includes a bubble eliminator for removing the oxygen bubbles that have been pulverized in the bubble pulverizer from the treated sewage, wherein the bubble eliminator comprises: a tank; An impeller stirring the treated sewage containing the pulverized oxygen bubbles in the tank; An impeller motor for rotating the impeller; And a screen for removing impurities including the pulverized oxygen bubbles in a lower region for discharging the treated sewage water from which the pulverized oxygen bubbles have been removed. As a result, the finely pulverized oxygen bubbles can be discharged to the outside, and only the high concentration dissolved oxygen can be efficiently supplied to the aerobic digestion tank.

Here, it further includes a detour pump for moving the treated sewage treated in the biological treatment tank to the bubble shredder. The sewage can be bypassed in consideration of the oxygen supply state of the aerobic digester.

According to the present invention, it is possible to reduce the power ratio and the area of the construction site by supplying the aerobic digestion tank with the oxygen required by the aerobic microorganism in a form that is dissolved in a high concentration in the sewage rather than the bubbles.

Yet another effect of the present invention is that the supply of micro-oxygen bubbles to the aerobic digestion tank is suppressed so that no suspended substances are generated in the aerobic digestion tank, so that the activity of the aerobic microorganisms can be effectively maintained.

1 shows a conventional wastewater treatment system.
2 is a block diagram of a sewage treatment system in accordance with an embodiment of the present invention.
3 is a view showing the structure of an oxygen mixer;
4 is a view showing a structure of a bubble pulverizer;
5 is a view showing the structure of the bubble eliminator.

Hereinafter, a sewage treatment system 1 according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a wastewater treatment system 1 according to an embodiment of the present invention, and Fig. 3 is a block diagram of a wastewater treatment system 1 according to an embodiment of the present invention, Fig. 4 is a diagram showing the structure of the bubble pulverizer 40, and Fig. 5 is a diagram showing the structure of the bubble remover 50. As shown in Fig.

 The sewage treatment system 1 includes an oxygen generator 30, an oxygen mixer 20, a bubble mill 40, a bubble remover 50, a feed pump 60 and a bypass pump 70.

The oxygen generator 30 is a device that removes contaminants from air and adsorbs nitrogen using an adsorbent, and then generates oxygen by concentrating the oxygen. The oxygen generator 30 has an air inlet and an oxygen outlet, and the oxygen outlet is connected to the oxygen mixer 20 so that oxygen can be supplied.

The oxygen mixer 20 draws the treated sewage to be treated in the biological treatment tank 10 and mixes oxygen generated by the oxygen generator 30 to the drawn sewage. The oxygen mixer 20 has a mixing pump 20-2 for withdrawing and moving the treated sewage overflowed from the aerobic digestion tank 10. The mixing pump 20-2 moves the processed sewage overflowed from the aerobic digestion tank 10 to the bubble pulverizer 40 while pressurizing the treated sewage together with the oxygen generated by the oxygen generator 30. The oxygen mixer 20 is moved to the bubble crusher 40 by the mixing pump 20-2 and oxygen bubbles are crushed while the oxygen and the sewage are mixed by the mixing body 20-1. The mixing body (20-1) has a structure (a) generating a large vortex so as to crush the oxygen bubbles mixed with the sewage or a structure (b) causing the velocity and the pressure change of the sewage containing oxygen bubbles, (C) that crushes oxygen bubbles. The mixing body 20-1 is provided in a tubular shape and has a large diameter and a small diameter, while the vortex and the pressure are varied to crush oxygen bubbles. The smaller the oxygen bubble, the larger the surface area becomes, and the larger the amount of oxygen dissolved into the sewage water.

The oxygen mixer 20 may be provided as a micro-bubble generator. The size of the minute bubbles generated by the micro bubble generator is about 100,000 times smaller than the size of the normal bubbles. The minute bubbles have about 100 times higher oxygen saturation than the normal bubbles generated by the general blower, Since the dissolved oxygen ratio is high, the same efficiency can be achieved with a small amount of power. For example, in order to make the amount of dissolved oxygen in the same sewage water, the amount of electric power of the general blower (about 60wh per m 3 of the wastewater) is about three times as much as the amount of electricity of the micro bubble generator (about 150wh per m 3 of wastewater). Thereby making it possible to remarkably reduce the power consumption.

The bubble pulverizer (40) crushes the oxygen bubbles contained in the treated sewage introduced from the oxygen mixer (20). The bubble mill (40) includes a grinding tank (40-1) in which oxygen-containing sewage is stored from the oxygen mixer (20). The bubble crusher 40 includes rotary crushing units 40-2 to 40-4 for crushing the oxygen bubbles contained in the treated sewage and a first motor 40 for rotating the rotary crushing units 40-1 to 40-3 -5). The rotary crushing units 40-1 to 40-3 are composed of a crushing rotary shaft 40-1, a crushing impeller 40-2 and a crushing brush 40-3. The crushing rotary shaft 40-1 is rotated by the first motor 40-5. The crushing rotary shaft 40-1 is vertically disposed at the center of the horizontal direction of the crushing tank 40-1, and a plurality of crushing impellers 40-2 are coupled in the transverse direction. Each of the pulverizing impellers 40-2 is equipped with a pulverizing brush 40-3 so as to pulverize oxygen bubbles in the sewage when the pulverizing rotary shaft 40-1 is rotated. The size of the fine bubbles generated by the bubble crusher 40 is about 0.1 to 10 mu m. The rotational speed of the crushing rotary shaft 40-1 can be determined by the experience value capable of generating minute bubbles.

The oxygen mixer 20 and the bubble pulverizer 40 maintain a pressure state higher than the atmospheric pressure. This can be done using a pressure valve that can pass over a certain pressure and creates a high pressure condition that allows the crushed oxygen bubbles to dissolve in the sewage as much as possible.

The bubble remover (50) removes the pulverized oxygen bubbles in the treated sewage containing the pulverized oxygen bubbles flowing from the bubbler (40). The bubble eliminator 50 is connected to the tank 50-4, the rotary shaft 50-1 and the impeller for stirring the processing sewage containing the pulverized oxygen bubbles in the tank 50-4 connected to the rotary shaft 50-1 The impeller motor 50-3 for rotating the impeller 50-2, and the foreign matter including the pulverized oxygen bubbles in the lower region for discharging the processed sewage water from which the pulverized oxygen bubbles have been removed, And a screen 50-5.

In the oxygen mixer 20 and the bubble pulverizer 40, the oxygen bubbles are crushed at a pressure higher than atmospheric pressure in order to dissolve oxygen in the sewage. However, the bubbler 50 removes the pressure of the oxygen bubbles in the sewage, 20 and the bubble pulverizer 40, the oxygen bubbles are moved at least to the upper portion of the tank 50-4. The oxygen bubbles can be moved to the upper portion of the tank 50-4 more quickly by the rotation of the impeller 50-2 which stirs the treated sewage. Thereby, the oxygen bubbles are prevented from being present in the lower part of the tank 50-4, and then the high concentration oxygen water from which the oxygen bubbles have been removed is taken out from the lower part of the tank 50-4 through the feed pump 60 to be discharged into the aerobic digestion tank 10 ).

The bypass pump 70 allows the treated sewage to be bypassed without passing through the oxygen mixer 20 and directly supplied to the bubble shredder 40 from the aerobic digester 10. The bypass pump 70 can bypass sewage in consideration of the oxygen supply state of the aerobic digestion tank 10. This is because the activity of the microorganisms must be controlled in consideration of the treatment state of the aerobic digestion tank 10 and another digestion tank, so that the sewage is bypassed when the amount of oxygen supplied to the aerobic digestion tank 10 should be reduced. A valve is provided at the branch point of the pipe to the bypass pump 70 and the pipe to the oxygen mixer 20, so that the flow path of the sewage can be adjusted. In addition, the central control panel may control the operation of the oxygen generator 30 and other components in consideration of this state.

In order to further remove fine bubbles, the bubbles are finely pulverized in the bubble grinder 40, and then a defoaming agent, which is a defoaming agent, may be added to remove bubbles. Since this defoaming agent is harmful to the microorganisms in the aerobic digestion tank 10, the defoaming agent may be neutralized by injecting the defoaming neutralizing agent into the bubble eliminator 50.

Because the sewage treatment system 1 does not supply the air supplied from the existing aerobic digestion tank by supplying the oxygen required by the aerobic microorganism to the aerobic digestion tank 10 in a form dissolved in the sewage rather than bubbles, Can be saved. In addition, since it is not necessary to supply air as in the existing aerobic digestion tank, the size of the aerobic digestion tank can be reduced. This makes it possible to reduce the site area of the aerobic digester. Further, the aerobic digestion tank 10 suppresses the supply of oxygen bubbles and supplies a high concentration of dissolved oxygen, so that suspended substances are not generated in the aerobic digestion tank 10. Whereby the activity of the aerobic microorganism can be effectively maintained.

1: sewage treatment system 10: aerobic digester
20: oxygen mixer 30: oxygen generator
40: air bubble grinder 50: air bubble eliminator
60: Feed pump 70: Bypass pump

Claims (6)

In a sewage treatment system,
A biological treatment tank to which oxygen is supplied;
An oxygen mixer including an oxygen generator for drawing out the treated sewage treated in the biological treatment tank and mixing the treated sewage with oxygen generated by the oxygen generator; And
And a supply pump for supplying treated sewage mixed with oxygen from the oxygen mixer to the biological treatment tank.
The method according to claim 1,
Further comprising a bubble grinder for crushing the oxygen bubbles mixed in the treated sewage in the oxygen mixer.
3. The method of claim 2,
The bubble pulverizer
A rotary crushing unit for crushing the oxygen bubbles contained in the treated sewage;
And a first motor for rotating the rotary crushing unit.
3. The method of claim 2,
Further comprising a bubble eliminator for removing the oxygen bubbles that have been pulverized in the bubble pulverizer from the processing wastewater.
5. The method of claim 4,
The bubble eliminator includes:
Tank;
An impeller stirring the treated sewage containing the pulverized oxygen bubbles in the tank;
An impeller motor for rotating the impeller;
And a screen for removing impurities including the pulverized oxygen bubbles in a lower region for discharging the treated sewage water from which the pulverized oxygen bubbles have been removed.
The method according to claim 1,
Further comprising a bypass pump for moving the treated sewage treated in the biological treatment tank to the bubble shredder.

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