KR20130071851A - Bubble eliminator for water treatment - Google Patents

Abstract

PURPOSE: A bubble eliminator for water treatment is provided to effectively remove bubbles, which is generated inside an aeration tank of all kinds of water treatment installations, by spraying air pressure with high pressure or high speed. CONSTITUTION: A bubble eliminator for water treatment comprises a rotator (4), an air supply pipe (8), and multiple air nozzles (6) equipped in a lower part of the air supply pipe. The rotator is connected to an air compressor (20), which is located on an upper side of an aeration tank (10), and controlled by a motor (30). The air supply pipe in which air pressure is supplied from the air compressor is connected in the rotator. The multiple air nozzles have a nozzle (6a) with micro diameter consisting of an injection needle. Air pressure is sprayed to bubbles through the nozzle with high pressure and high speed while the air supply pipe is rotated by the rotator, and the bubbles are removed.

Description

BUBBLE ELIMINATOR FOR WATER TREATMENT}

The present invention relates to a defoamer, and more particularly, to a defoamer for water treatment in which bubbles generated in tanks of various facilities requiring water treatment are quickly and more effectively destroyed and removed to obtain high efficiency at low cost.

In general, various facilities such as microbial fermentation aeration tank, fish farm aeration tank, wastewater treatment plant aeration tank, water purification plant aeration tank, etc. are used after the water treatment process inside the tank to purify the microbial growth and water.

In order to purify microbial fermentation, domestic wastewater and general wastewater, there is a tank for aeration as a purification treatment facility, and inside the tank, air is stored at the bottom of the tank to survive microorganisms to decompose contaminants and promote activation of the microorganisms. (Oxygen) is blown in. At this time, the air rises from the bottom, and a large amount of foam is formed on the surface of the water during the water treatment process.

A large amount of foam layer generated on the water surface of the tank decreases the efficiency of the purification function during water treatment, and if left unchecked, bubbles may leak out or evaporate out of the tank, causing bad smell to the surrounding environment. In other words, it provided the cause of secondary pollution.

Therefore, in order to minimize the occurrence of foam as described above, the conventional antifoam or antifoam was sprayed directly to the tank to prevent, but when using a chemical antifoaming agent it takes a lot of processing cost and has the disadvantage of lowering microbial growth, The injection of water is a separate inflow of water from the outside of the tank, which increases the amount of water treatment, which leads to an increase in unnecessary treatment time and an error in the planned flow rate.

In addition, there is a defoaming device that forcibly sucks bubbles generated in the tank and processes them.However, in the case of a suction defoamer, a suction pipe connected to a suction pump is installed on the surface of the tank to suck the foam and recover the foam. To make it flow back into the tank. However, it is difficult to forcibly introduce the bubbles generated by the wide distribution on the water surface into the suction tube, which takes a long time, and the liquid is sucked together with the bubbles through the suction tube, thereby reducing the work efficiency.

Accordingly, an object of the present invention is to spray bubbles generated in the aeration tanks of various water treatment facilities, such as a microbial fermentation aeration tank, a wastewater treatment plant aeration tank, and a water treatment plant aeration tank, by spraying air pressure at high pressure or high speed to destroy them quickly and effectively, It is to provide a defoamer for water treatment to obtain a high efficiency at a low cost while maximizing the water treatment work by controlling and spraying properly according to the amount and speed of foaming.

In accordance with the above object, the present invention, in the defoamer of the water treatment facility, the rotary body 4 is connected to the air compressor 20 on the upper side of the aeration tank 10 and controlled by the motor 30, and the A plurality of air supply pipes (8) supplied with air pressure from the air compressor (20) communicate with the rotating body (4), and a plurality of micro-diameter nozzles (6a) made of injection needles are provided below the air supply pipes (8). It is characterized in that the air injection port 6 of the air supply pipe 8 is rotated by the rotating body 4, the air pressure through the nozzle 6a at high pressure and high speed through the nozzle is characterized in that the configuration is configured to remove .

The present invention is connected to the air compressor on the upper side of the aeration tank of various facilities, such as microbial fermentation aeration tank, fish farm aeration tank, wastewater treatment plant aeration tank, water purification plant aeration tank, and a plurality of rotating air supply pipe and a nozzle of the injection needle at the bottom of the air supply pipe It is equipped with an air injection port to install a large amount of bubbles generated in the aeration tank during water treatment by spraying the air pressure at high pressure or high speed through the nozzle to destroy the bubbles quickly and effectively to obtain high efficiency at low cost.

In addition, the present invention is formed by inclining the angle of the nozzle of the injection needle to increase the work area by increasing the area of the high-pressure air is injected into the foam, the gap between the air injection ports installed in the air supply pipe toward the outside toward the narrower forming the nozzle While rotating, the high pressure air is sprayed in the same amount on the foam in the same amount to maximize the working efficiency.

1 is a configuration diagram using a bubble remover installed in the aeration tank according to an embodiment of the present invention,
2 is a perspective view of the present invention bubble remover,
3 is a front configuration diagram of the present invention bubble remover,
Figure 4 is a cross-sectional view of the main part of the present invention bubble remover,
5 is an injection state of the nozzle of the present invention,

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

The aeration tank 10 in which the bubble remover 2 of the present invention is installed is shown as an example consisting of a tank of a cylindrical drum, and it is revealed in advance that it can be applied and used according to various tank types such as aeration facilities.

Therefore, the defoamer (2) of the present invention is installed so that the rotating body (4) connected to the external air compressor (20) on the inner upper side of the aeration tank (10) is positioned, the plurality of air on the rotating body (4) Combining the air supply pipe 8 is provided with the injection port 6, the rotating body 4 is characterized in that the installation is configured to rotate in the aeration tank 10 is connected to the motor (30).

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a configuration diagram illustrating a state in which a bubble remover is installed in an aeration tank according to an embodiment of the present invention. With the aeration tank 10 made of a cylindrical drum, a rotor 4 having an air supply pipe 8 is installed in the center of the aeration tank 10 and positioned above, and the rotor 4 is an aeration tank ( The shaft is coupled to the rotating shaft 30a of the motor 30 fixedly installed on the outer surface of the bottom to rotate while supporting the shaft.

In this case, the motor 30 is most preferably using a motor that can be driven in the forward or reverse direction, and the motor 30 is electrically connected to the controller 40 through a sensor (not shown) to control the controller ( Controlling operation according to the driving command of 40 to control the rotation of the air supply pipe (8) installed in the rotating body (4) rotating from the rotating shaft (30a) to generate the bubbles generated on the surface of the aeration tank 10 To control the operation of the motor 30.

In addition, the rotating body 4 rotating from the motor 30 is connected to the pipe 20a as a rotary joint at the top thereof, and the rotating body 4 freely rotates while being axially supported by the pipe 20a. 20a) is connected to the air compressor 20 provided on the outside of the aeration tank 10, the compressed air sent from the air compressor 20 is introduced into the rotating body (4) to supply the air supply pipe (8) Make it happen.

At this time, between the pipe 20a and the air compressor 20 is provided with an on-off valve 20b, such as a solenoid valve to open and close the operation by an electrical signal through the control unit 40 depending on the operation of the motor 30. It is to control the supply of compressed air into the air supply pipe (8) installed on the whole (4).

On the other hand, the air supply pipe (8) installed on the rotating body (4) is a pipe body of the outer end is blocked, is in communication with the rotating body (4) horizontally coupled to both sides side by side horizontally on the upper surface of the aeration tank (10) Install in state. As shown in FIGS. 2 and 4, a plurality of air injection holes 6 are coupled to the lower part of the air supply pipe 8, and a nozzle 6a of an elongated tube of injection needles protrudes from the end of the air injection holes 9. It is formed so as to face the water surface so that the nozzle (6a) is installed as close as possible to the height of the bubbles generated on the water surface.

At this time, the nozzle 6a of the air injection port 6 is formed to be inclined at a predetermined angle from the air supply pipe 8 so that the high pressure air injected through the nozzle 6a is sprayed to the foam in the inclined direction as much as possible with the maximum area. However, depending on the size or amount of bubbles generated on the surface of the water, the nozzle 6a may be installed perpendicularly to the water and sprayed.

And the air injection port (6) having a lower portion of the air supply pipe (8) is configured so that the interval between the air injection port (6) gradually narrower toward the outside of the air supply pipe (8). This balances each other with the nozzle 6a of the inner air injection port 6 due to the rotation of the air supply pipe 8 by the rotor 4 when the nozzle 6a of the outer air injection port 6 rotates faster. In order to allow the amount of air to be injected into the foam to be sprayed in the same area, and to remove quickly while blocking the bubbles pushed out from the inside.

On the other hand, the nozzle 6a for removing bubbles is a long tube made of a needle, as mentioned above, and is formed with a micro diameter so as to break and remove bubbles by spraying air pressure at high pressure or high speed on the foam, and thus, removing the nozzle 6a. ) Should be small, but since it is difficult to process, the unit cost increases, so it is most preferable to form at least 0.1 to 2 mm. This is because when the nozzle 6a is formed to have a diameter of 2 mm or more, a large amount of air is injected, whereas the air pressure is not injected at high pressure or high speed, so that bubbles cannot be removed at once and bubbles are blown, so the removal effect is inferior. In particular, when the fine bubbles are removed, they cannot function again.

Therefore, the diameter of the nozzle 6a of the present invention is most ideally used at about 0.1 to 2 mm. Accordingly, the air compressor 20 also has an air pressure of about 1 to 20 kg / cm 2 depending on the diameter of the nozzle 6a. In this case, the air pressure sprayed through the nozzle 6a is sprayed onto the foam at a high pressure or high speed of 1 to 20 kg / cm 2 as it is.

Therefore, even when the air compressor 20 having a small capacity is provided with the nozzle 6a having the micro diameter, high pressure air pressure is injected from the nozzle 6a without overloading so that it can be easily removed without blowing bubbles. Even high efficiency can be obtained.

And the shape of the nozzle (6a) is in the form of a tube and the end is most ideal to form a circular shape, the end of the nozzle (6a) according to the amount and speed of foaming the various shapes of rectangular, square, polygonal and star shape It can be used to remove the foam by forming a.

Referring to the operating state to remove the bubbles generated in the aeration tank 10 using the bubble remover 2 of the present invention configured as described above are as follows.

When a large amount of bubbles are generated on the inner surface of the aeration tank 10 at the time of water treatment and reaches a predetermined level, a sensor (not shown) detects this and operates the motor 30 through the controller 40 to rotate The rotating force is transmitted to the entire body 4 so that both air supply pipes 8 rotate above the water surface, and at the same time, the compressed air is opened through the air compressor 20 by opening and closing the valve 20b receiving the electric signal from the controller 40. Supply is made to a rotating air supply pipe (8).

Thereafter, the compressed air supplied through the air compressor 20 is supplied to the nozzles 6a of the plurality of air injection holes 6 installed at the lower portion through the air supply pipe 8, and at this time, the end of the nozzle 6a of the injection needle Compressed air is blown as it passes over the foam as close as possible to the foam.

At this time, the compressed air injected through the nozzle 6a is injected through the micro nozzle 6a made of a long needle when the air pressure sent from the air compressor 20 is applied to an air pressure of, for example, 1 kg / cm 2. The air pressure is jetted with compressed air at the nozzle 6a at a high pressure or a high speed of about 1 to 20 kg / cm 2, which is easily blown away without blowing bubbles.

Therefore, when the diameter of the nozzle 6a in the present invention is used as a minimum of 0.1mm to a maximum of 2mm, in the case of small fine bubbles, the smallest possible diameter of the nozzle 6a is used to effectively remove the fine bubbles without blowing them. In the case of the foam, even if the diameter of the nozzle 6a is used, the foam can be sufficiently destroyed to remove the foam. Therefore, the foam can be appropriately used according to the amount and size of the foam.

Accordingly, even when the air compressor 20 having a pressure of removing bubbles through the micro-nozzle 6a made of the injection needle is about 1-20 kg / cm 2, the air pressure is high or high speed through the nozzle 6a without being sufficiently overloaded. Since the bubbles are sufficiently removed even with a small amount of air while being injected, it is possible to achieve high efficiency at low cost since it is unnecessary to use an air compressor of high pressure while maximizing the use efficiency of the air compressor 20 further.

Also, the nozzle 6a is sprayed at a high pressure or a high speed, and the nozzles 6a are formed to be inclined at a predetermined angle from the air supply pipe 8 so that the sprayed air is inclined to the foam in as many areas as possible. As the installation intervals of the air injection holes 6 having the nozzles 6a are gradually narrowed toward the outside of the supply pipe 8, the same amount of air pressure is injected into the same area according to the rotation radius of the rotating air supply pipe 8. Zooming further maximizes the efficiency of defoaming.

Therefore, bubbles are quickly removed by the high pressure air pressure sprayed through the nozzle 6a when the air injection holes 6 of the air supply pipe 8 are rotated at the upper surface of the aeration tank 10, and then abandoned. A sensor (not shown) detects a bubble removing state in the tank 10, stops the operation of the motor 30 through the control unit 40, and simultaneously closes the on / off valve 20b to the air supply pipe 8. Bubble removal is completed by blocking the incoming air pressure. When the bubble is generated again, the bubble remover 2 is restarted to repeatedly perform the bubble removing operation.

In addition, in the present invention, the bubble remover (2) is automatically operated under the detection of bubbles generated in the aeration tank (10). You can also implement it in several ways.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments but should be determined by the equivalents of the claims and the claims.

The present invention can be used to defoam various water treatment plants.

(2)-defoamer (4)-rotating body
(6)-Air nozzle (6a)-Nozzle
(8)-Air supply line (10)-Aeration tank
(20)-Air compressor (20a)-Piping
(20b)-open / close valve (30)-motor
(30a)-axis of rotation (40)-control unit

Claims (5)

In the defoamer of the water treatment facility, a rotary body (4) connected to the air compressor (20) above the aeration tank (10) and controlled by a motor (30), and an air compressor (3) on the rotary body (4). The air supply pipe 8 through which air pressure is supplied from 20 is communicatively coupled, and the lower part of the air supply pipe 8 is provided with a plurality of air injection holes 6 having micro-diameter nozzles 6a of injection needles. And defoamer for water treatment, characterized in that the air supply pipe (8) is rotated by the rotating body (4) so that air pressure is injected into the foam at high pressure and high speed through the nozzle (6a).
According to claim 1, The air supply pipe (8) side by side horizontally coupled to both sides of the rotating body (4) rotated from the motor 30, a plurality of air injection holes (6) provided in the lower portion of the air supply pipe (8) The defoamer for water treatment, characterized in that configured to gradually form a narrower gap from each other toward the outside of the air supply pipe (8).
The nozzle 6a of the injection needle provided in the air injection port 6 provided below the air supply pipe 8 is formed to be inclined at a predetermined angle from the air supply pipe 8, so that the high pressure air bubbles in the inclined direction. Defoamer for water treatment, characterized in that to spray on.
The defoamer for water treatment according to claim 1, wherein the nozzle (6a) made of the injection needle is in the form of a tube, and the diameter of the nozzle (6a) is formed to be 0.1 to 2 mm.
The defoamer for water treatment according to claim 1 or 4, wherein the end of the tubular nozzle (6a) is formed into one of a circle, a rectangle, a square, a polygon, and a star to inject high pressure air.

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