KR950009969Y1 - Aerator - Google Patents

Abstract

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Description

Aeration device to increase dissolved oxygen

Figure 1 is an overall configuration of the device the present invention is installed.

2 is an exploded perspective view of the present invention.

3 is an exploded perspective view of the sealing plug of the present invention.

* Explanation of symbols for main parts of the drawings

10: compressor 15,25,35: exhaust pipe

20: discharge tube 30: air storage tank

31: exhaust hole 40: air exhaust pipe

41: protrusion 42: quantity monitoring window

43,44: water level detection sensor 45: drain hole

50: plug built-in 51: plug

52: spring body storage container connector 53: air discharge hole

54: spring body storage container 55: countercurrent blocking spring body

The present invention relates to an aeration apparatus that mixes ionized air with incoming water and aerations it, thereby increasing the dissolved amount of oxygen in the water.

Conventionally, there has been a device for increasing the amount of oxygen dissolved in water, but it is simple in structure and lacks aeration means, so it is not possible to destroy the air minutely. Not only did it not increase the dissolved amount, but the water purification ability was so insignificant that it was only a device that partially dissolved oxygen. Therefore, in order to increase the dissolved amount of oxygen in the water stored in a large volume of space, more energy and equipment are required, resulting in an increase in installation cost and an increase in the occupied space of the apparatus.

The purpose of the present invention is to provide a device that can solve the above defects, improve the water purification ability and greatly increase the dissolved amount of oxygen, which will be described in detail with reference to the accompanying drawings.

The exhaust pipe 15 of the compressor 10 driven by the motor M is connected to one end of the discharge tube 20 discharged by the electrode, and between the other end of the discharge tube 20 and one end of the air storage tank 30. In the air ionization generator having an exhaust pipe 25 connected to the lower end of the air storage tank 30, and having an exhaust hole 31 having a built-in shock spring, a built-in cylinder 50 of the plug 5 is provided. An exhaust pipe 35 is connected between the protrusion 41 having a through-hole formed in the upper portion of the combined air discharge pipe 40 and the other end of the air storage tank 30, and a solenoid at an outlet of the air discharge pipe 40. An air discharge pipe 60 opened and closed by the valve SV _{2 is} connected to an inlet pipe 65 and a T-shaped pipe 64 opened and closed by the solenoid valve SV ₃ , and an air pipe having a built in pipe 70 ( 75) is connected to the structure.

In addition, inside the air discharge pipe 40, water level detection sensors 43 and 44 for detecting the surroundings are installed on the inner wall of the air discharge pipe 40 at a predetermined interval, and the surroundings are visually identified in the center. The water quantity monitoring window 42 is formed to be covered with a transparent material, and the lower end side of the pipe 40 has a structure in which a drain hole 45 is opened and closed by a solenoid valve SV ₁ .

Furthermore, several cross-sectional crystals are formed in the width pipe 75 formed in the resin material 70 and the width pipe 75 itself is spirally wound and filled with a material such as Homica to be fixed in the pipe 70. It is installed structure.

When explaining the application effect of the present invention having the above structure as follows.

By the driving of the motor M, the compressed air is formed in the compressor 10. When the compressed air passes through the exhaust pipe 15 into the discharge tube 20 discharged at a predetermined voltage, the air is ionized and passes through the pipe 25 to enter the air storage tank 30. A predetermined amount of ionized compressed air can be stored in the air storage tank 30, and when the amount becomes more than that, a buffer spring (not shown) is built in, and the air discharge hole 31 is opened and closed by air pressure. Exhaust through). When the air in the air storage tank 30 reaches an appropriate amount during the exhaust, the exhaust hole 31 is closed so that there is no further exhaust. The ionized compressed air discharged from the air storage tank 30 passes through the pipe 40 in which the water quantity monitoring window 42 is formed, and passes through the through hole 53 penetrating from the top to the bottom of the plug 51.

Therefore, it is pushed down by the backflow blocking spring pressure which seals the through hole 53, and the compressed air passes through the air discharge pipe 60 through the air discharge pipe 60 through the space inside the formed through hole 53. It begins to mix with the water coming in. The mixed air enters into the spiral width pipe 75 fixed in the pipe 70. The spiral width pipe 75 is filled with an angled object with a polyhedron (not a tetrahedron), so that air mixed with water passing through it is more finely destroyed and mixed with water, thereby improving water purification ability. In this state, water passing through the width pipe 75 becomes like a bubble and enters a designated reservoir (not shown). Therefore, the water stored in the reservoir is better purified than ordinary water, and the dissolved oxygen is increased and stored, so that when used in a large reservoir tank, a swimming pool or a fish farm of the apartment, more bright and clean water can be encountered. In this way, since the countercurrent blocking spring body 55 is in an open state while water and air are subjected to a constant circulation process, water obtained at a predetermined pressure may flow back into the air discharge pipe 50. Therefore, when the water flowed back in the pipe 40 to some extent, the water level detection sensor 43, 44 detects this. When the drain port 45 is opened or closed by the opening and closing operation of the solenoid valve SV ₁ attached to the lower end side of the pipe 40 according to the detection signal of the detection sensors 43 and 44, the air discharge pipe 60 is opened. The solenoid valve (SV ₂ ) attached to one side of the) and the solenoid valve (SV ₃ ) attached to one side of the inlet pipe 65 are operated to close the respective pipes 60 and 65 to block the flow of water. When the air discharge pipe 60 is sealed, the compressed air introduced into the air discharge pipe 40 through the air storage tank 30 and the water flowing back into the pipe 40 are discharged together through the drain hole 45. The pipe 40 is returned to its original state with no water at all, and when no water is detected by the water level detection sensor 44, the controller (not shown) operates according to the signal of the water level detection sensor 44. By operating two solenoid valves (SV ₁ , SV ₂ , SV ₃ ) The solenoid valve SV ₁ of the sphere 45 is shut off, and the solenoid valves SV ₂ and SV _{3 of the} air discharge pipe 60 and the inlet pipe 65 are kept open, so that water and air are normally mixed. Done. Despite the opening and closing operations of the respective solenoid valves SV ₁ , SV ₂ , and SV ₃ , the compressor 10 and the discharge tube 20 perform an existing function.

Claims (3)

The exhaust pipe 15 of the compressor 10 driven by the motor M is connected to one end of the discharge tube 20 discharged by the electrode, and between the other end of the discharge tube 20 and one end of the air storage tank 30. In the air ionization generator having an exhaust pipe 25 connected thereto, and an exhaust hole 31 having a built-in buffer spring formed at a lower end side of the air storage tank 30, an internal cylinder 50 of the plug 5 is provided. An exhaust pipe 35 is connected between the protrusion 41 having a through-hole formed in the upper portion of the combined air discharge pipe 40 and the other end of the air storage tank 30, and a solenoid at an outlet of the air discharge pipe 40. An air discharge pipe 60 opened and closed by the valve SV _{2 is} connected to an inlet pipe 65 and a T-shaped pipe 64 opened and closed by the solenoid valve SV ₃ , and an air pipe having a built in pipe 70 ( 75) aeration device characterized in that the structure is connected to. According to claim 1, wherein the air discharge pipe 40, the water level detection sensors 43, 44 for detecting the water level is provided on the inner wall of the air discharge pipe 40 at a predetermined interval, the central portion is Quantity monitoring window 42 is formed to be able to visually identify the water level is covered with a transparent material, the lower end of the pipe 40 is a structure in which the drain opening 45 is opened and closed by the solenoid valve (SV ₁ ) Aeration device characterized in that. According to claim 1, wherein the inside of the resin pipe formed in the pipe (70) contains several polyhedral crystals and the pipe (75) itself is wound spirally and filled with a material such as Homica and pipe 70 An aeration device characterized in that the structure is fixed to the inside.