KR200441952Y1 - Aeration-type apparatus for producing ozonized water - Google Patents

Abstract

The present invention relates to a device for producing ozone water by aeration of ozone gas into water, a tank into which water is temporarily stored and temporarily stored, an aeration unit that generates ozone water by aeration of ozone gas into water stored in the tank, and the ozone water And a guide member disposed in the tank to surround the drain pipe, and guide the ozone water to the drain pipe at a predetermined distance or less from the drain pipe.

According to the aeration ozone water production apparatus of the present invention, it is possible to continuously produce ozone water that does not contain gaseous ozone. In addition, the amount of ozone water to be produced can be adjusted, and ozone water having a different concentration of dissolved ozone gas can be produced.

Aeration, Ozone Water, Ozone Water Manufacturing Equipment

Description

Aeration-type apparatus for producing ozonized water}

1 is a cross-sectional view of a conventional aeration ozone water production apparatus,

2 is a cross-sectional view of the aeration ozone water production apparatus according to a first embodiment of the present invention,

3 is a cross-sectional view of the aeration ozone water production apparatus according to a second embodiment of the present invention.

＊ Explanation of symbols for main part of drawing ＊

100 tank 200 aeration part

300: drain pipe 400: guide member

500: connector 550: valve

600: ozone removal unit

The present invention relates to a device for producing ozone water by aeration of ozone gas into water, and more particularly, it is possible to continuously produce ozone water that does not contain ozone in the form of gas, and It relates to an aeration ozone water production apparatus that can adjust the concentration.

In general, ozone water in which ozone is dissolved in 1 ppm or more in water has a strong sterilization, deodorization, and purification function, and ozone dissolved during the performance of this function is decomposed into oxygen. Therefore, ozone water is widely used in group feeding facilities, hydroponic cultivation facilities, livestock farms, and aquaculture farms.

At home, ozone water can be used for sterilizing drinking water, deodorizing and disinfecting sinks and kitchen containers, and removing residual pesticides from fruits. In addition, ozone water is also effective in the treatment of skin diseases, and has recently attracted attention as a home bath water.

Such ozone water production methods are classified into aeration method, injector method, and electrolysis method. In the aeration method, ozone gas is continuously aerated in water to dissolve ozone gas in water to produce ozone water. The injector method produces ozone water by passing ozone gas and water through a Venturi tube and mixing and dissolving it in a portion of the water. The electrolysis method is to produce ozone water by electrolyzing water directly.

However, the injector method is difficult to produce a large amount of ozone water in a short time, the electrolysis method has a problem that the life of the electrode is short and expensive. Therefore, the aeration method is widely used as a method of producing a large amount of ozone water at a low cost.

The apparatus for producing ozone water by a conventional aeration method is as shown in FIG. Conventional aeration ozone water production apparatus is largely composed of a tank 10, aeration portion 20, drain pipe 30, exhaust pipe 40 and ozone removal unit 50.

The tank 10 is where the water flowing through the water supply pipe 15 is temporarily stored. In addition, the aeration unit 20 generates ozone water by aeration of the ozone gas introduced through the ozone gas supply pipe 25 to the water stored in the tank 10. The ozone water generated in this way is discharged to the outside through the drain pipe (30).

On the other hand, the ozone gas remaining in the upper portion in the tank 10 is not dissolved in water is discharged to the outside through the exhaust pipe (40). At this time, the ozone gas is decomposed and discharged in the form of oxygen gas and oxygen ions by the ozone removing unit 50 installed in the exhaust pipe 40.

In the conventional aeration type ozone water production apparatus, a portion of the ozone gas bubbles generated in the aeration section 20 and scattered near the ozone water level surface in the tank 10 are provided in an overflow manner. There was a problem of mixing with ozone water through the drain pipe (30). In addition, there is a problem that ozone gas remaining on the upper portion of the tank 10 may also come out through the drain pipe 30 according to a change in the amount of water and ozone gas introduced into the tank 10.

However, unlike ozone water, such gaseous ozone has a strong smell, is toxic, and reacts with gases in the atmosphere to form volatile organic compounds and nitrogen oxides. Ozone gas, volatile organic compounds and nitrogen oxides are harmful substances that stimulate human respiratory or ocular mucosa.

Therefore, the conventional aeration ozone water production apparatus has a problem that can cause fatal damage, such as polluting the air or damage the health of the user.

An object of the present invention for solving the above problems is to provide an aeration-type ozone water production apparatus that can continuously produce ozone water that does not contain ozone in the form of gas.

The aeration type ozone water production apparatus of the present invention for achieving the above object is a tank in which water is temporarily introduced and stored, aeration unit for generating ozone water by aeration of the ozone gas stored in the tank, the ozone water discharge And a guide member provided in the tank to surround the drain pipe and allowing the ozone water to flow into the drain pipe at a predetermined distance or less from the drain pipe.

The aeration ozone water production apparatus of the present invention may further include a connection pipe connected to the upper portion of the guide member to communicate with the gas inside the tank, and an ozone removal unit for removing ozone gas introduced through the connection pipe.

The drain pipe may be provided in the form of a pipe extending from the lower portion of the tank to the middle portion. In addition, the guide member has a diameter exceeding the diameter of the drain pipe, is covered up to a predetermined height from the tank, the lower portion may be provided in the form of an open tube.

The ozone removing unit may be provided outside the tank. In addition, the aeration portion may be installed lower than the upper end of the drain pipe, higher than the lower end of the guide member.

The aeration ozone water production apparatus of the present invention may further include a valve for adjusting the amount of gas introduced through the connecting pipe.

Hereinafter, with reference to the accompanying drawings will be described in detail to be easily carried out by those of ordinary skill in the art with respect to the embodiment of the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

Hereinafter, an aeration type ozone water production apparatus according to Embodiment 1 of the present invention will be described in detail with reference to FIG. 2.

As shown in Figure 2, the aeration ozone water production apparatus according to the first embodiment of the present invention is a tank 100, aeration unit 200, drain pipe 300, guide member 400, connecting pipe 500 ), And the ozone removal unit 600.

The tank 100 is a place for temporarily storing the water introduced by the water supply pipe 150. In addition, the tank 100 is a place where ozone gas supplied by the aeration unit 200 is dissolved in the water. The tank 100 may be manufactured in various sizes according to the amount of ozone water that can be produced per hour.

The aeration unit 200 generates ozone water by aeration of the ozone gas introduced through the ozone gas supply pipe 250 into the water stored in the tank 100. The aeration unit 200 is made of a porous member, it is preferable to be configured to maximize the contact area with water by dispersing ozone gas in the form of a plurality of bubbles.

The drain pipe 300 discharges the generated ozone water to the outside of the tank 100 to supply the user. In the aeration ozone water production apparatus according to the first embodiment of the present invention, the drain pipe 300, as shown in Figure 2, is provided in the form of a pipe extending from the lower portion to the middle portion of the tank 100 do.

The guide member 400 allows the ozone water to flow into the drain pipe 300 at a predetermined distance or less from the drain pipe 300. In general, ozone water in the tank 100 is scattered in the ozone gas bubbles generated in the aeration unit 200 near the water level surface, because the bubbles rise to the water level surface by buoyancy in the water due to the characteristics of the gas.

The guide member 400 prevents the ozone water near the water level surface in which the ozone gas bubbles are scattered in such a manner that the guide member 400 is prevented from flowing into the drain pipe 300 and the ozone gas bubbles are almost absent from the bottom surface of the tank 100. Allow nearby ozone water to flow into the drain. Therefore, the guide member 400 achieves the effect of blocking the ozone gas bubbles from flowing into the drain pipe 300.

The connecting pipe 500 communicates the inside of the guide member 400 with the inside of the tank 100 to maintain the same air pressure therein. Therefore, the connecting pipe 500 is connected to the upper portion of the guide member 400 so as to communicate with the gas present in the upper portion of the tank (100).

As such, the connection pipe 500 maintains the air pressure inside the guide member 400 and the air pressure inside the tank 100 so that the drain pipe 300 forms a siphon structure together with the guide member 400. And prevent the drain pipe 300 from forming an overflow structure. In addition, the connecting pipe 500 keeps the pressure inside the tank 100 stable.

Hereinafter, the role of the connector 500 as described above will be described in more detail.

If the connection pipe 500 is not provided, the drain pipe 300 forms a siphon structure together with the guide member 400. In this case, when the water supply to the tank 100 is blocked or the amount of water is reduced, the ozone water level in the tank 100 is lowered to the siphon level S by the siphon principle. As such, when the ozone water level in the tank 100 is lowered, there is a possibility that the ozone gas bubbles that existed in the vicinity of the water level surface of the ozone water are discharged out through the drain pipe 300.

On the contrary, when the connecting pipe 500 is provided, when the ozone water level is lowered below the overflow level (0), ozone water is no longer introduced into the guide member 400 due to the density difference between the gas and the liquid. Instead, the gas in the tank 100 is introduced into the guide member 400 through the connecting pipe 500.

Therefore, the drain pipe 300 maintains the overflow structure, and even if the water supply to the tank 100 is blocked or the water supply amount is reduced, the ozone water level does not fall below the overflow level (O). Therefore, even in this case, the ozone gas bubbles are prevented from being discharged out through the drain pipe 300.

As described above, when the gas in the tank 100 flows into the guide member 400, the connecting pipe 500 controls the amount of gas passing through the connecting pipe 500. It may further include. The valve 550 is used to adjust the amount of ozone water produced by the aeration ozone water production apparatus by adjusting the amount of gas passing through the connecting pipe 500 to adjust the level of the ozone water.

Hereinafter, a process of adjusting the concentration of dissolved ozone gas by the valve 550 according to the amount of ozone water produced in the aeration ozone water production apparatus will be described in detail.

First, when increasing the amount of ozone water produced in the aeration ozone water production apparatus should increase the amount of water flowing through the water supply pipe 150. At this time, the amount of ozone gas dissolved through the ozone gas supply pipe 250 must also be increased to keep the amount of ozone gas dissolved in the ozone water constant. However, it is preferable that the amount of ozone gas introduced through the ozone gas supply pipe 250 be constant because of cost, maintenance cost reduction, and ease of maintenance.

Therefore, when the amount of water introduced through the water supply pipe 150 is increased, in order to produce ozone water having the same concentration, the ozone gas bubbles generated by the aeration unit 200 are increased to increase the time that water is in contact with the ozone. Make sure the gas is more soluble in water. By increasing the ozone water level in the tank 100 by one of the methods, the ozone gas bubbles may be in contact with water for a longer time, thereby increasing the amount of ozone gas dissolved in the water.

On the other hand, by reducing the amount of gas passing through the connecting pipe 500 by using the valve 550, the pressure of the gas in the tank 100 by the amount of water rapidly flowing through the water supply pipe 150 The pressure of the gas in the guide member 400 is higher. In addition, the amount of gas that can pass through the connecting pipe 500 is reduced, so that the pressure of the gas in the tank 100 and the pressure of the gas in the guide member 400 cannot be equal to each other only by the movement of the gas. . Therefore, the level of ozone water in the tank 100 is increased due to rapid water inflow. Then, the amount of ozone water discharged through the drain pipe 300 is increased by increasing the water pressure.

Then, when the amount of ozone water discharged through the drain pipe 300 is sufficiently increased to compensate for the amount of gas passing through the connecting pipe 500, the water level of the ozone water does not increase any more, so that the water level is maintained. do. As described above, the ozone gas bubbles come into contact with water for a longer time due to the increased level of ozone water, thereby increasing the amount of ozone gas dissolved in the water. Therefore, the aeration ozone water production apparatus can produce a large amount of ozone water per hour in which the concentration of dissolved ozone gas is not reduced through the operation of the valve 550.

On the contrary, in order to reduce the amount of ozone water produced by the aeration ozone water production apparatus, the amount of water introduced through the water supply pipe 150 is reduced, and the gas is connected to the connection pipe 500 through the operation of the valve 550. Increase the amount that can pass through. Then, the pressure of the gas in the tank 100 and the pressure of the gas in the guide member 400 can be maintained the same through the movement of the gas so that the ozone water level is not higher than the overflow level O. Therefore, the aeration ozone water production apparatus is capable of producing a small amount of ozone water per hour in which the concentration of dissolved ozone gas is not increased.

By applying the above-described method, by adjusting the water inflow through the water supply pipe 150 and the valve 550, the amount of dissolved ozone gas is a large amount of high concentration ozone water and dissolved ozone gas This low concentration of ozone water can also be produced.

That is, increasing the amount of water inflow and increasing the amount of gas flow through the connecting pipe 500 through the operation of the valve 550, the ozone water level is not higher than the overflow level (O), so that the ozone water having a low concentration is produced. On the contrary, if the water inflow is reduced and the gas flow through the connecting pipe 500 is increased through the operation of the valve 550, the ozone water level is increased to produce ozone water having a high concentration.

In the aeration ozone water production apparatus according to Embodiment 1 of the present invention, the valve 550 is provided so that the gas in the tank 100 may pass before the ozone removing unit 600, but the gas is the ozone agent. It may be provided to pass through the rejection 600 first.

As described above, when the valve 550 is provided in the aeration ozone water production apparatus, the aeration ozone water production apparatus further includes a display device (not shown) that informs the user of the ozone water level in the tank 100. It may include.

The ozone removing unit 600 removes ozone gas introduced into the guide member 400 through the connecting pipe 500. As described above, when the ozone water level in the tank 100 is lowered below the overflow level O, the connection pipe 500, the gas inside the tank 100 through the guide member 400. It is to be discharged to the drain port (300). At this time, the gas inside the tank 100 contains a large amount of ozone gas that is not dissolved in water, the ozone removal unit 600 by removing such ozone gas when passing through the connecting pipe 500, It is to prevent the ozone gas is discharged through the drain port (300).

The ozone removing unit 600 may be provided inside the tank 100, but considering the possibility of replacing the ozone removing unit 600 and the ease of repair due to a reduction in removal efficiency, It is preferable to be provided externally. The ozone removing unit 600 decomposes and removes ozone gas (O ₃ ) into oxygen gas (O ₂ ) and oxygen ions (O ^{2 −} ) using a catalyst material such as activated carbon. In this case, the ozone removing unit 600 may be provided to apply heat to the ozone gas through a hot wire or the like to increase the removal efficiency.

On the other hand, ozone gas remaining in the upper portion of the tank 100 without dissolving in water is discharged to the outside through the exhaust pipe (700). At this time, the ozone gas passing through the exhaust pipe 700 is removed through a separate ozone remover 800. In consideration of the removal efficiency of ozone gas, the ozone removal unit 600 and the ozone remover 800 are preferably provided separately, but the aeration ozone water producing apparatus includes the connection pipe 500 and the exhaust pipe 700. It may be implemented in the form of sharing this one ozone removal unit 600.

Hereinafter, the operation of the aeration ozone water production apparatus according to Embodiment 1 of the present invention.

First, when water is introduced into the tank 100 through the water supply pipe 150, the aeration unit 200 aeration of the ozone gas introduced through the ozone gas supply pipe 250 in the introduced water to ozone water Create In addition, the ozone water is guided by the guide member 400 from the bottom surface of the tank 100, which does not contain ozone gas bubbles, is discharged to the outside through the drain port 300 and supplied to the user.

On the other hand, the ozone gas remaining in the upper portion of the tank 100 without dissolving in water of the ozone gas aerated by the aeration unit 200, the oxygen gas through the exhaust pipe 700 and the ozone remover 800 And it is discharged to the outside in the oxygen ion state. In addition, some of them move to the guide member 400 in the state of oxygen gas and oxygen ions through the connecting pipe 500 and the ozone removing unit 600, and is discharged to the outside through the drain port 300.

Hereinafter, an aeration type ozone water production apparatus according to Embodiment 2 of the present invention will be described in detail with reference to FIG. 3. However, the aeration ozone water production apparatus according to the second embodiment of the present invention is the aeration ozone water production apparatus according to the first embodiment of the present invention except for the position and shape of the drain pipe 300 and the guide member 400 The configuration and operation are similar.

As shown in Figure 3, the aeration ozone water production apparatus according to a second embodiment of the present invention is provided so that the drain pipe 300 and the guide member 400 has an overflow structure of a different manner. In addition to the overflow structure, various implementation methods are known, and the second embodiment of the present invention may change the position and shape of the drain pipe 300 and the guide member 400 according to the implementation method. Shows.

That is, the aeration ozone water production apparatus, the guide member 400 guides the ozone water from the vicinity of the bottom surface of the tank 100 to the drain port 300, the connection pipe 500 is the tank 100 If provided to maintain the same pressure inside the guide member 400, the drain pipe 300 and the guide member 400 may be implemented in an overflow structure of various ways.

As described above, according to the aeration type ozone water production apparatus of the present invention, it is possible to discharge the ozone water near the tank bottom surface that does not contain the ozone gas bubbles to supply to the user.

In addition, the aeration ozone water production apparatus can maintain a stable pressure in the tank irrespective of the amount of water and ozone gas flowing into the tank, it is possible to prevent the ozone gas bubbles from mixing extensively with the ozone water in the tank.

Thus, according to the aeration ozone water production apparatus, it is possible to continuously produce ozone water that does not contain gaseous ozone.

In addition, by adjusting the valve, it is possible to produce ozone water having a different concentration of dissolved ozone gas, and can separately control the amount of ozone water produced per hour.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various modifications and changes are possible within the technical spirit of the present invention, and those belonging to the utility model registration claims to which such modifications and modifications are attached. Is a matter of course.

Claims (7)

In the apparatus for producing ozone water by aeration of ozone gas into water, A tank into which water is introduced and temporarily stored; An aeration unit for generating ozone water by aeration of ozone gas into water stored in the tank; A drain pipe through which the ozone water is discharged; And A guide member provided in the tank to surround the drain pipe and allowing the ozone water to flow into the drain pipe at a predetermined distance or less from the drain pipe; Aeration ozone water production apparatus comprising a. The method of claim 1, A connecting pipe connected to an upper portion of the guide member so as to communicate with gas in the tank; And An ozone removal unit for removing ozone gas introduced through the connection pipe; The aeration ozone water production apparatus further comprising a. The method according to claim 1 or 2, The drain pipe, The aeration ozone water production apparatus, characterized in that provided in the form of a tube extending from the lower portion of the tank to the middle portion. The method of claim 3, The guide member, The aeration ozone water production apparatus having a diameter exceeding the diameter of the drain pipe, and covered over a predetermined height from the tank, the lower portion is provided in the form of an open tube. The method of claim 2, The ozone removal unit, The aeration ozone water production apparatus, characterized in that provided on the outside of the tank. The method according to claim 1 or 2, The aeration unit, The aeration ozone water production apparatus, characterized in that lower than the upper end of the drain pipe, higher than the lower end of the guide member. The method according to claim 2 or 5, A valve for controlling the amount of gas introduced through the connecting tube; The aeration ozone water production apparatus further comprising a.

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