KR101781357B1 - Variable control aerator for water purification - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a variable control and aeration apparatus for purifying water, and more particularly, to a variable control and aeration apparatus for purifying water quality by effectively supplying oxygen or the like to water to help purify water quality. A variable control and aeration apparatus for purifying water according to the present invention comprises: a plurality of buoyancy means floating on a water surface; A frame coupled to the buoyancy means such that the plurality of buoyancy means are interconnected; Aeration means coupled to the frame; And a displacement means for coupling the aeration means to the frame so that one end of the aeration means is submerged in the water, wherein the displacement means adjusts the inclination between the one end of the aeration means immersed in water and the water surface . Thus, the variable control and aeration apparatus for purifying the water as described above can adjust the inclination of the aeration means, thereby achieving uniform stirring and proper air injection according to the water quality of the water to be purified, thereby purifying water quality efficiently and effectively have.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable control apparatus for purifying water,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable control and aeration apparatus for purifying a water, and more particularly, to a variable control and aeration apparatus for purifying water for efficiently purifying water by efficiently supplying oxygen or the like to water, .

Recently, there has been an increasing number of cases where water quality deteriorates in places such as sewage treatment plants and fish farms. A device for improving water quality by decomposing organic matter by promoting the activity of microorganisms in water by supplying oxygen in water is widely developed and used in a lake / wastewater treatment plant or a lake where lakes are likely to occur due to eutrophication have. In addition, in order to produce fish or plants such as fish farms or farms, the amount of dissolved oxygen (dissolved oxygen) in the water must be more than a certain amount. This is because the organic matter in the water is stabilized by the action of aerobic microorganisms and requires a certain amount of oxygen in order to be purified naturally. An air pump or an air blower is installed for supplying oxygen.

In recent years, a miniaturized aeration device has been used due to its simplicity of portability and maintenance convenience. A representative example thereof is Korean Patent No. 10-1219540 (Water Purification Aerator), which is the right of applicant of the present invention On March 23, the rights were transferred to Cheongwoo Ace by the merger of Blue Water Co., Ltd. and Cheongwoo Ace).

Korean Patent No. 10-1219540 discloses a device for purifying a water quality which is fixed on a frame such that one end of the aeration means floats on the frame while the aeration device floats on the water surface, And an air discharge path for supplying air into the water, and purifies the water quality by injecting air at the same time as stirring. The miniaturized aeration device can effectively purify water by stirring and air injection at the same time. It is smaller and easier to use than existing water purification devices, and has advantages of simplicity of portability and ease of maintenance.

However, as a result of using the Korean Patent No. 10-1219540 (aquarium purification aeration apparatus) by the applicant, it has been found that the above-described water quality purification and aeration apparatus can not flexibly and effectively cope with water quality conditions. In other words, although it is preferable that other purification methods are applied according to the condition and condition of water quality, there is a problem that the invention of the applicant can not actively change the purification method according to the water quality conditions and conditions. That is, although the state of the water quality to be purified differs depending on the place, the water purification aeration apparatus can not have satisfactory agitation efficiency due to difficulty in changing the stirring method regardless of the water quality state. In this case, excessive use of the motor in order to increase the stirring efficiency causes an overload to the aeration device, which leads to failure and life span of the water purification and aeration device. Also, since the passage of the air to be injected into the inflow hole and the air inflow pipe is determined, it is difficult to control the agitation and the aeration capacity variably. As a result, the water to be purified is not purified, the purification efficiency is low, and the ultimate purpose of using the water quality purification and aeration device can not be achieved. In other words, the effect of agitation and the effect of aeration are unclear and need to be supplemented. That is, the present invention relates to a variable control and aeration apparatus for purifying a water capable of simultaneously performing stirring and aeration.

Korean Patent No. 10-1219540

Accordingly, it is an object of the present invention to at least partially solve the above problems and / or disadvantages and to provide at least the advantages described below. Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, It is possible to control the amount of air supplied according to the condition of the water quality so that it can be controlled by the uniform stirring and the proper air And an object of the present invention is to provide an aeration apparatus for improved water quality purification so as to achieve injection.

In order to solve the above problems, a variable control and aeration apparatus for purifying water according to the present invention comprises a plurality of buoyancy means floating on the water surface, and a plurality of buoyancy means coupled to the buoyancy means so that the plurality of buoyancy means are interconnected A method of controlling an air conditioner, comprising: a frame; aeration means coupled to the frame; and a displacement adjusting means for coupling the aeration means to the frame so that one end of the aeration means is submerged in water, wherein the aeration means adjusts the inclination between the one end of the aeration means immersed in water and the water surface Wherein the aeration means includes a first valve and a second valve for supplying air into the water, a stirring means provided at one end of the aeration means immersed in water, and a motor for operating the stirring means, Wherein at least one of the first valve and the second valve is opened according to a result of automatic measurement of dissolved oxygen, Further comprising an air blower provided at one side of the frame for selectively controlling at least one of the first valve, the second valve and the stirring means to operate the first valve and the second valve, And a second end connected to the air blower and injecting the air generated in the air blower into the water, wherein the first end is connected to the air blower and the second end is connected to the air blower, And selectively controlling ON / OFF of at least one of the first stage and the second stage.

In addition, the displacement means can control the inclination between the one end of the aeration means and the water surface from 0 to 90 degrees, and the displacement means is capable of controlling one end of the aeration means in at least one of the up and down movement and the left- Can be controlled.

In addition, a control lever is attached to one side of the displacement means, and the inclination formed between one end of the aeration means and the water surface by the operation of the control lever may be adjusted, and the displacement means may receive a control signal transmitted wirelessly And adjust the inclination between the one end of the aeration means and the water surface in accordance with the control signal.

Further, it may further include an inverter for controlling the rotational force of the motor.

The variable control and aeration device for purifying the water as described above can control the inclination of the aeration means and can achieve uniform stirring and proper air injection according to the water quality of the water to be purified, thereby purifying the water efficiently and effectively. In particular, depending on the condition of the water quality, it may be necessary that the stirring and the supply of air need to be performed only not far from the surface of the water, or from the water surface to the bottom, the variable control and aeration device according to the invention, It is possible to control the degree of inclination from 0 to 90 degrees so that the rotational force of the stirring means can be transmitted to the bottom of the water as well as the amount of air supplied to the water can be controlled, Thereby enabling effective purification of water.

1 is a perspective view of a variable control and aeration apparatus for water purification according to an embodiment of the present invention.
2 is a cross-sectional view of a variable control and aeration apparatus for water purification according to an embodiment of the present invention.
3 is a perspective view for explaining aeration means according to an embodiment of the present invention.
4 is an enlarged perspective view of the first and second valves.
5 is a driving control block diagram of a variable control and aeration apparatus according to an embodiment of the present invention in Fig. 5; Fig.
6 is a graph for explaining aeration (air injection) efficiency of a variable control and aeration apparatus according to an embodiment of the present invention.
FIGS. 7A, 7B and 7C are diagrams showing that the motor rotational force can be adjusted through the inverter. FIG.
FIG. 8A is a view for explaining a case where only stirring is performed, and FIG. 8B is a view for explaining an example in which stirring and aeration (air injection) are performed at the same time.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a variable control and aeration apparatus for purifying water according to the present invention will be described in detail with reference to the drawings.

The variable control and aeration apparatus 100 for water purification according to the present invention is similar in structure to the prior art patent registration No. 10-1219540. At least two valves are provided for controlling the inclination of the aeration means and for smoothly and appropriately controlling the amount of air supplied into the water. In addition, an inverter for controlling the rotational force of the motor is added, The function and configuration capable of controlling the speed are improved as compared with the prior art. In addition, an internal air discharge impeller 251 is provided inside the shaft tube, so that air can be more efficiently transferred to the water.

The variable control and aeration apparatus 100 for water purification according to the present invention includes a plurality of buoyancy means 110 floating on the water surface, as shown in Figs. A frame (120) coupled on the buoyancy means (110) such that a plurality of buoyancy means (110) are interconnected; Aeration means (200) coupled to the frame (120); And a displacement means 150 for coupling the aeration means 200 to the frame 120 so that one end of the aeration means 200 is immersed in the water. Adjust the slope of the first and the sleep.

The buoyancy means 110 is made of a material that can float on the water surface and has a buoyancy capable of floating the frame 120 and the aeration means 200. As the buoyancy means 110, a plastic buoyancy member including air, styrofoam, or the like may be used. However, the present invention is not limited thereto, and any means can be applied as long as the variable control and aeration apparatus 100 according to the present invention can float on the surface. It is possible. The buoyancy means 110 are arranged so that four are balanced as shown in Fig. 1, so that the variable control and aeration apparatus 100 can stably float on the water surface without being stranded on the water surface.

The frame 120 is a component that allows the buoyancy means 110 to be connected in a balanced manner and is supported on the buoyancy means 110 to support the aeration means 200. The frame 120 is made of a rigid material such as plastic, metal, alloy, aluminum, etc., and a space in which the air blower 130 is installed is provided on one side of the frame 120. The air blower 130 is a device for supplying air to the aeration means 200. The air blower 130 has a blowing fan inside and sucks the outside air and forces the air into the aeration means 200. Since the air blower 130 is a well-known device, a detailed description thereof will be omitted.

Aeration means 200 is installed in the frame 120 so as to be positioned at the center of the four buoyancy means 110. The configuration of the aeration means 200 has a structure similar to that disclosed in Korean Patent No. 10-1219540 (Water Purification Aerator), which is a right of the applicant. 3, the aeration means 200 according to the present invention includes a flange 210, a motor 220, an axial pipe 230, a rotary shaft 240, a support pipe 250, (260). A discharge impeller 251 for injecting air into water is provided inside the shaft tube. The discharge impeller 251 is a discharge device capable of forcibly injecting the air introduced into the atmosphere or the air introduced from the air blower 130 into the water, thereby enhancing the efficiency of air injection. In other words, not only a large amount of air can be injected in a short time, but also the air can be discharged into deeper water due to the earth output.

The difference from the conventional applicant's right is that at least two valves 252 and 254 are provided in the support tube 250 and that an inverter 225 for controlling the rotation of the motor ) Is added. As shown in FIGS. 3 and 4, the first valve 252 and the second valve 254 are substantially 'T' -shaped and have three ends. One end of the three ends is connected to the support tube 250, the other end (first end, 256) extends into the atmosphere to supply air in the air, and another end (second end, 258 Is connected to the air blower 130 to inject air generated in the air blower 130 into the water. The connection between the second stage 258 and the air blower 130 is connected through a separate pipe (not shown). The first valve 252 and the second valve 254 may be solenoid valves (solenoid valves) or air control valves. Here, although the terms of the respective valves are different, the function is the same as injecting outside air into the water. However, the amount of air to be injected may be varied by selectively varying the sizes and sizes of the valves. It goes without saying that the size and the size of the two valves can be made the same. Closing means 259 for opening and closing each valve is provided at the end of each of the valves 252 and 254. The operator opens and closes the opening and closing means 259 of each of the end portions 256 and 258 in order to optimally purify them according to conditions and conditions of water quality .

That is, in comparison with the conventional aeration apparatus, the present invention uses at least one of the first valve 252 and the second valve 254 based on the value measured by the oxygen measurement sensor 310, The stirring means 260 can be operated by starting. The operator can selectively control at least one of the first valve, the second valve and the agitating means on the basis of the measured value, so that the operator can actively change the purification method according to the condition and condition of the water quality . For example, if it is determined based on the value measured by the oxygen measurement sensor 310 that the stirring is sufficient, the motor 220 can be started and stirred only. 5, the rotational force of the agitating means 260 may be changed to a desired level by the inverter 225 for controlling the rotational force of the motor. As will be described later, the inclination angle of the aerator 200 So that the stirring performance is transmitted from the water surface to the bottom depending on the condition of the water quality.

If it is determined that both the stirring and the aeration (air injection) need to be performed simultaneously, only the first end 256 connected to the atmosphere of each of the valves 252 and 254 is opened, and by the start of the motor 220 The stirring means 260 is rotated. Here, only the first end 256 of either valve may be opened according to the state of the water quality. The first end 256 of each valve 252 and 254 is closed and the second end 258 is opened and the second end 258 and the air blower 130 The air blower 130 can be controlled to rotate the stirring means 260 by the start of the motor 220 while the air is forcedly supplied to the water by the operation of the air blower 130. [ And only the second end 258 of one of the two valves may be opened depending on the condition of the water quality. All such control is performed by the control unit 320.

The method for purifying the water according to the condition and condition of the water quality may be changed according to the judgment of the operator, but it is preferable that the method is automatic. That is, when the measurement result (dissolved oxygen concentration, etc.) of the oxygen measurement sensor 310 is obtained, the result is transmitted to the control unit 320. Based on the measurement result, the control unit 320 determines, Whether to use only one of the two valves 252 and 254, or both of them, or whether to use either one of the two ends 256 and 258 or both of them may be determined according to predetermined criteria. The control unit 320 controls the inverter 225 based on the measurement result of the oxygen measurement sensor 310 such as dissolved oxygen concentration and the inverter 225 can control the rotational force of the motor 220.

In another embodiment, although not shown, four valves may be physically separate and formed on the support tube 250, respectively. That is, the first and second ends of the first and second valves described above are physically separated and formed on the support tube 250, respectively, and the function thereof is the same as the previously described embodiment. That is, the two first ends are connected to the atmosphere and the second two ends are connected to the air blower 130, respectively.

On the other hand, the aeration means 200 is installed in the frame 120 through the displacement means 150. The displacement means 150 according to the present invention is configured to control an angle (i.e., an inclination) formed by one end of the aeration means 200 with the water surface, as shown in Fig. The displacement means 150 can control the inclination between the one end of the aeration means 200 and the water surface to be 0 to 90 degrees. Further, the displacement means 150 can control one end of the aeration means 200 in at least one of a vertical movement and a lateral movement.

Specifically, the displacement means 150 is configured such that both ends of the lower end portion of the aeration means 200 are hinged to both sides of the frame 120. The aeration unit 200 is fixedly coupled to the frame 120. In the present invention, the inclination of the aeration unit 200 is freely adjustable. Such a displacement means 150 may be manually adjusted in inclination or may be automatically adjusted in inclination.

First, the displacement means 150 in which the inclination degree is manually controlled will be described. 1, a flange 210 protruding from both sides of the lower end of the aeration means 200 is formed with a coupling hole, and the frame 120 around the region where the aeration means 200 is mounted also has a projection And a coupling hole is also formed in the projecting portion. The two engaging holes are positioned so as to correspond to each other with the outer surface of the protruded bent flange 210 corresponding to the inner surface of the protrusion of the frame 120 and the displacement means 150 ) Are coupled to the two coupling balls. A control lever 151 is attached to one side of the displacement means 150 and the inclination between the one end of the aeration means 200 and the water surface is controlled by the operation of the control lever 151. For example, in the simplest case, when the control lever 151 is rotated to the left, the coupling force of the displacement means coupled to the coupling hole is loosened, and when the coupling force is loosened, And the lever 151 is turned to the right to fix the lever 151 firmly.

As another example, although not shown, a screw having a gear at its end may be coupled to a coupling hole of the flange 210, and a gear receiving groove may be formed in the frame so as to engage with the gear. A control lever is attached to the other side of the gear. Accordingly, when the control lever is rotated, the inclination of the aerator 200 is controlled by the engagement of the gear and the gear seat. That is, since the frame 120 is fixed and does not move and the aeration means 200 mounted on the gear seating groove 122 rotates, the aeration means 200 moves up and down as the gear slides on the gear seating groove It will be done. In this case, the depth at which one end of the aeration means 200 is immersed in the water also can be controlled as well. The length of the gear seating groove is determined based on the number of gear teeth and the shape of the gear teeth so that one end of the aerator 200 faces the water surface and the zero- To 90 [deg.] Inclined range. For example, when the gear is located at the innermost position of the gear receiving groove, the aeration means 200 is inclined at almost 90 degrees, and the end portion of the aeration means 200 is deepest in the water. On the other hand, when the gear is located at the outermost position of the gear receiving groove, the aeration means 200 is disposed in a substantially horizontal state, and the depth of the end portion of the aeration means 200 is also minimized. Here, after the inclination is adjusted, fixing means (not shown) for restricting the movement of the gear may be added, and it is preferable that the gear is protected by a case (not shown) so that engagement of the gear and the gear receiving groove is not released. It goes without saying that, in addition to the above-described methods, any of those capable of controlling the inclination of the aeration means 200 can be freely applied and used.

Meanwhile, the horizontal movement of the aeration means 200 may be provided such that the aeration means 200 moves left and right along the rotation axis. A part of the aeration means 200 coupled to the rotating shaft is provided with a screw in the direction of the rotating shaft so that when the screw is loosened, the aeration means can move left and right along the longitudinal direction of the rotating shaft. And fixed at one point.

Hereinafter, an example of automatically adjusting the inclination of the aeration means 200 will be described.

The displacement means 150 may receive a control signal transmitted wirelessly and adjust the inclination between the one end of the aerator 200 and the water surface in accordance with the control signal. In this case, the displacement means 150 includes a motor, a rotary shaft, and a drive belt. A motor (not shown) for rotating the rotating shaft is provided on the other side of the frame 120, one side of the motor is connected to the driving belt, and the other side of the driving belt is connected to the rotating shaft. The rotating shaft is configured to pass through the aeration means 200. Accordingly, the motor is started by the control signal of the control unit 320, and the rotational force of the motor is transmitted to the rotating shaft along the driving belt, so that the aerator 200 can move up and down. The lateral movement of the aeration means 200 can also be realized by a motor, a drive belt, and a rotary shaft. That is, the principle that the ink nozzle of the laser printer moves left and right can be applied as it is. In addition, the aeration means 200 can be moved to the left or right or can be moved up and down in various manners using well-known techniques known before the invention of the present invention. That is, the above-described embodiment is merely one example, and it is natural that a typical technician can implement various methods using ordinary creative ability.

The reason why the upper and lower and left and right angles of the aeration means 200 can be adjusted by using the displacement means 150 is that the rotational force by the stirring means 260 can be transmitted to the bottom. This is because it is important that the rotational force is transmitted from the water surface to the bottom in order to maintain the uniform microbial concentration (MLSS) of the bioreactor. It is well known that the concentration of microorganisms is an important component for the purification of water quality. When the oxygen in the air is delivered to the bottom, the activity of microorganisms at the bottom is activated by the oxygen, and the number of the population is increased, It is a maximized principle. For the same reason, if the angle of the aeration means 200 is also adjustable, a more uniform microbial concentration (MLSS) becomes possible and the purification efficiency is improved. However, whether or not the rotational force should be transmitted to the bottom should be decided according to the condition and condition of the water quality. This is because it may not be necessary to transmit the rotational force of the stirring means 260 to the floor depending on the condition and conditions of the water quality.

Hereinafter, the experimental results according to the embodiments of the present invention and the experimental data for supporting the effects of the present invention will be described in detail with reference to the drawings.

6 is a graph showing a change in dissolved oxygen concentration in water with time when air is injected into the water (fresh water standard) using the variable control apparatus according to the present invention. As shown in FIG. 6, it is confirmed that the aeration capability of the variable control apparatus 100 of the present invention is very smooth. In addition, it can be confirmed that the dissolved oxygen concentration increases as the aeration time increases. In particular, the increase rate of the dissolved oxygen concentration is improved in about 30 minutes, which is a result of improved microbial activity (microbial concentration) and natural purification efficiency in about 30 minutes.

FIGS. 7A, 7B and 7C are diagrams showing that the motor rotational force can be adjusted through the inverter. FIG. FIG. 7A shows a case where the motor is controlled to rotate at 800 rpm by inverter control, FIG. 7B shows a case where it is controlled to rotate at 1000 rpm, and FIG. As described above, it is possible to control the rotational force of the motor by inverter control, and it can be confirmed that the stirring efficiency is improved as the rotational force is increased.

The table below shows the difference in SS concentration before and after stirring according to the distance from the water surface due to the rotational force of the aeration means 200.

In the first frame of the table, the SS concentration was measured at a point 1.5 m from the surface of the water. The SS concentration was 2 mg / L before the aeration means 200 was operated, but it was 68 mg / L after the operation. In the second frame of the table, the SS concentration was measured at a point 0.5 m from the water surface. It can be seen that the SS concentration was 2 mg / L before the aeration means 200 was operated, but 62 mg / L after the operation. Therefore, it can be seen that uniform stirring is taking place due to the operation of the aeration means 200.

FIG. 8A is a view for explaining a case where only stirring is performed, and FIG. 8B is a view for explaining an example in which stirring and aeration (air injection) are performed at the same time.

FIG. 8A shows an example in which the water quality is maintained by maintaining an oxygen-free condition, and is applied to a case where even mixing of the stirring means 260 can maintain uniform mixing.

FIG. 8B shows an example of decomposing contaminants and inducing nitrification by smooth air supply, in which the efficiency of oxygen transfer is increased through the generation of minute bubbles, and the stirring efficiency is increased.

The invention made by the inventors of the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the gist of the invention. It is to be understood that the inventive concepts and embodiments of the invention disclosed herein may be modified or altered by those skilled in the art as a basis for modifying or designing other structures to carry out the same purposes of the invention, It is obvious that it belongs to the scope of right.

100: variable control and aeration device 110: buoyancy means
120: frame 130: air blower
150: displacement means 200: aeration means
210: flange 220: motor
225: inverter 230:
240: rotation shaft 250: support tube
251: Discharge impeller 252: first valve 254: second valve 256: first stage 258: second stage 259: opening / closing means 260: stirring means 310: oxygen measuring sensor 320:

Claims (9)

A plurality of buoyancy means floating on the water surface;
A frame coupled to the buoyancy means such that the plurality of buoyancy means are interconnected;
Aeration means coupled to the frame;
And a displacement means for coupling the aeration means to the frame so that one end of the aeration means is submerged in water and for controlling the inclination between one end of the aeration means immersed in water and the water surface,
The aeration means includes a first valve and a second valve for supplying air into the water, a stirring means provided at one end of the aeration means immersed in water, and a motor for operating the stirring means. The automatic measurement of dissolved oxygen in water Selectively controlling at least one of the first valve, the second valve and the agitating means so as to open at least one of the first valve and the second valve or operate the agitating means by starting the motor ,
Further comprising an air blower provided at one side of the frame,
The first valve and the second valve each include a first end extending in the air and supplying air in the air into the water and a second end connected to the air blower and injecting the air generated in the air blower into the water In addition,
And selectively controlling on / off of at least one of the first stage and the second stage according to a result of automatic measurement of dissolved oxygen in the water. The method according to claim 1,
Wherein the displacement means controls the inclination between one end of the aeration means and the water surface from 0 to 90 degrees. The method according to claim 1,
Wherein the displacement means controls one end of the aeration means in at least one of a vertical movement and a lateral movement. The method according to claim 1,
A control lever is attached to one side of the displacement means,
Wherein the inclination of the one end of the aeration means with the water surface is controlled by the operation of the control lever. The method according to claim 1,
Wherein the displacement means receives a control signal transmitted in a wireless manner and adjusts the inclination between the one end of the aeration means and the water surface in accordance with the control signal. delete delete The method according to claim 1,
Further comprising an inverter for controlling the rotational force of the motor. ≪ RTI ID = 0.0 > 11. < / RTI >
delete

Images