KR100465755B1 - air bubble solution apparatus - Google Patents

Abstract

The present invention relates to a bubble dissolving device, the object of which is to break the bubble having a large particle diameter into the rotating blade of the impeller rotated at high speed to make a very fine micro-bubble that floats only about 1m per hour to contact the liquid to be treated. In this way, it is possible to obtain a highly contact oxidation effect as well as a dissolution effect dramatically.

In the bubble dissolving device according to the present invention, the impellers 13 and 14 for generating fine bubbles are mounted on the output rotating shaft 12 of the underwater motor 10, which are radially formed when viewed from the bottom and have a plurality of rotary vanes having stepped portions. 13a is formed in a sawtooth shape. An impeller protecting member 15 is formed at a lower end of the submersible motor 10 to surround the fine bubble generating impellers 13 and 14, and the impeller protecting member 15 has a slit at a lower end of the submersible motor 10. The formed partition wall 15a extends downward, and the filter 15d of a cup cross section is covered by the lower end of this partition wall 15a. The gas injector 16 is connected to the gas injection hose 16a, which receives air from the ground compressor, to the underwater motor 10, and at the end of the gas injection hose 16a of the impeller 13 for generating fine bubbles. The gas injection pipe 16b is connected to the branch injection nozzle 16c in the center.

Description

Air bubble solution apparatus

The present invention relates to a bubble dissolving apparatus capable of ensuring an efficient dissolution rate of a gas by contacting water or seawater with a gas such as oxygen or ozone in a very fine micro bubble state.

In general, water sinks are generated in closed waters such as lakes, swamps, dams, aquaculture plants, and combined septic tanks when eutrophication water quality becomes oxygen deficient. This was done, but only a slight effect could be expected. The reason for this is that the particle size of the bubbles to be brought into water and brought into contact with them is large enough to rise immediately, and thus the effect of increasing the dissolved oxygen in the water cannot be expected.

According to the advanced literatures so far, when a gas such as oxygen (O) or ozone (O ₃ ) is injected into and contacted with a liquid, the contact area with the liquid is large because the particle diameter of 0.2, 0.3 to 2, 3 mm corresponds to a large bubble. Not only is it small, but the gas rises quickly, so the contact time with the liquid is short, and the gas dissolution rate into the liquid is very low.

Therefore, as an alternative to increase the gas dissolution rate into the liquid, a study in which the contact tank has a cylindrical shape and the liquid in the contact tank is rotated to increase the contact time even slightly, or the arrangement requiring more time for the liquid ( Although studies have been conducted to increase the effect by adding a larger amount of gas by using a batch method, even water flowers cannot be removed by oxygen aeration in a real pond or swamp.

In addition, even if the existing waste treatment facility or the combined septic tank is aerated, the particle size of the input gas is large. Therefore, the aeration tank itself is largely secured, and the size of the corresponding gas is similar for the oxygen aeration during aquaculture fishing. The low rate of dissolution into the liquid, that is, because the dissolved oxygen rate cannot be enhanced, it is not possible to implement a high-density aquaculture as well as a high mortality rate due to disease or oxygen deficiency.

Under these circumstances, there is an urgent need for the development of new technologies that can be expected to be cheaper, more reliably and safely into the liquid.

An object of the present invention was invented to solve the above-mentioned problems, rather than injecting a gas having a large particle size, such as a conventional oxygen aeration or ozone aeration, the air bubbles having a large particle diameter are finely cut by the rotary blades of the impeller to rotate at high speed It can be made into very fine microbubble that only floats about 1m per hour, and can be put into contact with the liquid to be treated.Therefore, it provides a bubble dissolving device that can achieve a high contact oxidation effect as well as a dissolution effect. have.

In addition, since the present invention is directly used in water, such as an underwater pump, improved water quality in closed waters such as lakes, swamps and dams, red tide measures and water flower removal, oxygen deficiency measures, oxygen supply and purification of fish farms, and oxygen in a combined purification tank. It is to provide a bubble dissolving device suitable for aeration.

1 is a cross-sectional view schematically showing a bubble generating apparatus according to the present invention.

Figure 2 is a perspective view showing an extract of the impeller in Figure 1;

3 is a bottom view of FIG. 2.

<Explanation of Signs of Major Parts of Drawings>

10: submersible motor 11: electric cord

12: output rotary shaft 13, 14: impeller for generating fine bubbles

15: impeller protective member 15a, 15b, 15c: partition wall

15d: filter 16: gas injector

16a: gas injection hose 16b: gas injection pipe

16c: branch injection nozzle

Bubble dissolving device according to the present invention for achieving the above object is an underwater motor connected to the electric cord is supplied power from the ground; Fine bubble generating impeller formed radially and saw a plurality of rotary blades having a stepped tooth when viewed from the bottom to break the bubbles having a large particle diameter to the output rotation shaft of the underwater motor; An impeller protection member having a partition formed with a slit at a lower end of the submersible motor so as to surround the fine bubble generating impeller, and having a filter having a cup-shaped cross section at the lower end of the partition wall; The gas injection hose, which receives air from the ground compressor, is connected to the underwater motor, and the gas injection pipe is connected to the gas injection pipe so that the branch injection nozzle is located at the end of the gas injection impeller at the end of the gas injection hose. It features.

In addition, the microbubble generating impeller is installed in two stages by extending the output rotation shaft of the underwater motor and extends the length of the partition wall as the output rotation shaft of the underwater motor is extended, the outer part of the microbubble generating impeller located at the bottom The partition wall is characterized in that only the fine bubbles are discharged through the partition wall is formed with a slit, the bubble having a large particle diameter is formed as a partition without a slit so that the flow is guided to the upper fine bubble generating impeller.

The partition wall is characterized in that the slit becomes smaller gradually as the upper portion rises to the lower portion of the fine bubble generating impeller.

EMBODIMENT OF THE INVENTION Hereinafter, it demonstrates in detail with reference to attached drawing which is a preferable embodiment of this invention.

1 is a cross-sectional view schematically showing the bubble generating apparatus according to the present invention, Figure 2 is a perspective view showing an extract of the impeller in Figure 1, Figure 3 is a bottom view of FIG.

As shown in the figure, the underwater motor 10 is connected to the electric cord 11 is supplied with commercial power of 220V and 110V from the ground, the output rotating shaft 12 which is a rotor of the underwater motor 10 is fine bubbles With the impellers 13 and 14 for generating, it is used as a maneuvering force to generate very fine micro bubbles by rotating about 3000 ~ 6000 times per minute, so the output of the submersible motor 10 is small from about 100W to about 5KW. It is required to establish a specification. The reason is that when the output of the submersible motor 10 is weak and the rotational speed of the submersible motor 10 is small, the bubbles are not pulverized well and the bubbles become larger.

The fine bubble generating impellers 13 and 14 are installed in two stages at a predetermined interval on the output rotation shaft 12 of the submersible motor 10, which is radial when viewed from the bottom so as to break up bubbles having a large particle diameter. As a result, a plurality of rotary blades 13a having stepped teeth are formed in a sawtooth shape. The upper surfaces of the fine bubble generating impellers 13 and 14 are irrelevant to the generation of fine bubbles, and thus may be formed to have a flat surface to minimize resistance to liquid.

At the lower end of the submersible motor 10, an impeller protecting member 15 for discharging microbubbles while wrapping the impellers 13 and 14 for generating microbubbles is mounted, and the impeller protecting member 15 is an underwater motor 10. The partition walls 15a, 15b, and 15c extend from the lower surface of the bottom surface thereof, and the filter-shaped cross section filter 15d is covered on the lower ends of the partitions 15a, 15b and 15c. Since the partition walls 15a, 15b, and 15c efficiently discharge the micro bubbles generated by the rotary vanes 13a of the fine bubble generating impellers 13 and 14, slits are formed, and the slits are formed in particular. The partition wall 15b outside the bubble generating impeller 13 is discharged through the upper part of the partition wall 15a in which only fine bubbles are formed, and the bubbles having a large particle diameter of the remaining fine bubble are formed at the upper part of the impeller 14. It is formed by the partition wall 15b without a slit so that the furnace flow is guided.

The slit-formed partition walls 15a and 15c have a smaller slit as they rise upward from the lower portion of the fine bubble generating impellers 13 and 14 so as to break or break the bubbles more finely.

The filter 15d prevents inhalation of mud, small stones, sand, or organic foreign matters, which may cause the occurrence of microbubbles or failure.

In addition, the submersible motor 10 is provided with a gas injector 16 to supply gas from the ground to the fine bubble generating impeller 13, the gas injector 16 is a gas (air) from the ground compressor Gas injection hose 16a is supplied to the submersible motor 10, and branch injection nozzles 16c are positioned at the lower end of the gas injection hose 16a at the bottom of the center of the impeller 13 for generating fine bubbles. The gas injection pipe 16b is connected as much as possible.

All parts of the device of the present invention described above should be operated in sewage, sea water or ozone atmosphere in addition to the general water quality, so that they must be able to withstand the use in these atmospheres such as vinyl chloride, stainless steel, or titanium. .

The two stage fine bubble generating impellers 13 and 14 fixed to the output rotating shaft 12 of the submersible motor 10 are specifications of a large-capacity processing, that is, a large apparatus, and small and medium specifications for small-volume processing are required. If it is necessary to generate a relatively large microbubble, and to require a flow of water rising by pressure and injury on the water surface, one of the two microbubble impellers 13 and 14 can be installed by installing an impeller for microbubble generation. Can be.

In the figure, reference numeral 16d denotes an adjustment valve for adjusting the amount of gas injected through the gas injection hose 16a.

Bubble dissolving device according to the present invention configured as described above, the water quality of the water to be treated, such as lakes, swamps, dams, water quality improvement, red tide measures and water flower removal, oxygen deficiency measures, oxygen supply and purification of the farm And operate with aeration of oxygen aeration such as a combined septic tank required.

First, since the output rotary shaft 12 is rotated while power is applied to the underwater motor 10 by turning on the power switch, when the fine bubble generating impellers 13 and 14 on the output rotary shaft 12 begin to rotate, Water is discharged radially through the partition wall (15a, 15c) is formed with a slit. At the same time, a phenomenon in which water is sucked through the filter 15d below the partition 15a is repeated. The filter 15d prevents inhalation of mud, small stones, sand, or organic foreign matter, which may cause the generation of microbubbles or failure.

In this state, when the compressor is operated to supply gas (air) through the branch injection nozzle 16c via the gas injection hose 16a and the gas injection pipe 16b, it is radially formed on the fine bubble generating impeller 13. Due to the rotary blade (13a) to push the water adjacent to the rotary blade (13a) radially.

Therefore, since a negative pressure is generated in the central portion of the fine bubble generating impeller 13, the gas supplied to the branch injection nozzle 16c rises to the center portion of the fine bubble generating impeller 13. In addition, connecting the gas injection hose 16a to the gas injection pipe 16b is for convenience of movement. The branching nozzles 16c are branched into several parts to prevent the bubbles of the microbubbles from expanding when a large amount of air is injected at one time.

At this time, if the amount of gas supplied from the compressor is large, the bubbles of the fine bubbles are similarly increased. Therefore, it is necessary to provide the finest fine bubbles by providing and adjusting the adjusting valve 16d in the gas injection hose 16a. .

As such, when the gas reaches the central portion of the fine bubble generating impeller 13, the gas is finely crushed and broken by the step of the rotary blade 13a rotating at high speed, and the finest fine bubbles are generated. This is largely due to the shape and rotation speed of the generating impeller 13.

In other words, since the shape of the rotary blade 13a of the fine bubble generating impeller 13 is radial when viewed from the bottom and is serrated when viewed from the side, when rotating at high speed, that is, the central part of the fine bubble generating impeller 13, that is, the rotary blade The contracted portion of (13a) is in a vacuum state, and when a gas (air) mass is sent thereto, it is finely crushed and split into fine bubbles. The lower part of the microbubble generating impeller 13 is radially swirled in the rotational direction thereof, and heavy water (liquid) hits the partition wall 15a in which the slit is formed by centrifugal force and discharges it outward from the slit. It is becoming. At this time, since the fine microbubbles have little buoyancy, they are discharged together with water (liquid) through the bottom of the partition wall 15a in which the slits are formed.

On the other hand, bubbles that have not yet been miniaturized by the rotary vanes 13a of the fine bubble generating impeller 13 are buoyant as the larger bubbles have larger buoyancy, so even if they try to be discharged through the upper portion of the partition wall 15a in which the slit is formed. Since it hits the partition 15b which does not have a slit, it cannot pass. Therefore, when the relatively large bubbles that are not refined are raised to the upper side by the bulkhead 15b having no slit, the fine bubble generating impeller 14 in the upper position is also caused by the fine flow generating impeller 14 due to the swirl flow generated by the high speed rotation. It is fed upwards toward the center of the center.

Subsequently, the process of refining the bubbles is refined by the rotary blades 13a of the fine bubble generating impeller 14 by the method described above, and all directions along with water (liquid) through the partition wall 15c in which the slits are formed. Is discharged.

At this time, the fine bubbles discharged from the fine bubble generating impellers 13 and 14 are generated in a range of 10 to 30 μ, which is extremely fine, so that when the same amount of gas is introduced into the liquid, it is possible to contact and dissolve and promote oxidation very efficiently. Done.

Therefore, since the microbubbles generated in the apparatus of the present invention are very fine, the floating speed is slow, and it is possible to drift with the water current in the water and to dissolve the oxygen efficiently in the water. Can be maximized.

In addition, the effect of oxidizing the organic matter in the water or scattering nitrogen in the air can also be expected, and may be attached to the surface of the water by attaching fine bubbles to the very fine water flower.

In addition, even when extremely fine bubbles are introduced into the farm, the amount of dissolved oxygen can be remarkably increased, so that the amount of cultured in a certain area can be increased, as well as the promotion of fattening and the prevention of disease. do.

As described in detail above, the bubble dissolving device according to the present invention is made into a very fine microbubble that breaks up a bubble having a large particle diameter with a rotary blade of an impeller rotated at a high speed to make a very fine microbubble that floats only about 1m per hour, and puts it in the liquid to be treated. It can be contacted, and accordingly there is a distinctive effect that can be obtained in a drastically high catalytic oxidation effect as well as dissolution effect.

In addition, since the apparatus of the present invention is directly used in the water, such as an underwater pump, water quality improvement of closed waters such as lakes, swamps and dams, red tide measures and water flower removal, oxygen deficiency measures, oxygen supply and purification of farms, combined purification tanks, etc. Is especially effective for oxygen aeration.

Claims (3)

An underwater motor 10 to which an electric cord 11 that receives power from the ground is connected; A fine bubble generating impeller in which a plurality of rotary blades 13a having a stepped tooth are radially formed when viewed from the bottom surface of the submerged motor 10 in order to finely break bubbles having a large particle diameter. 13,14); A partition wall 15a having a slit formed at the lower end of the submersible motor 10 to surround the fine bubble generating impellers 13 and 14 extends downward and a cup-shaped filter 15d at the lower end of the partition wall 15a. Impeller protection member (15); The gas injection hose 16a, which receives air from the compressor on the ground, is connected to the submersible motor 10, and the branch injection nozzle (3) is formed at the end of the gas injection hose 16a at the end of the impeller 13 for generating fine bubbles. And a gas injection pipe (16d) connected to the gas injection pipe (16d) such that 16c) is positioned. According to claim 1, The fine bubble generating impeller (13,14) is installed in two stages by extending the output rotation shaft 12 of the underwater motor 10, the output shaft 12 of the underwater motor (10) The barriers 15a, 15b, and 15c extend as much as they extend, and the barrier ribs 15b of the outer portion of the fine bubble generating impeller 13 positioned below are discharged through the barrier ribs 15a in which only fine bubbles are formed. And a bubble having a larger particle size of the remaining particles is formed as a partition wall (15b) having no slit so as to guide the flow to the upper fine bubble generating impeller (14). 3. The bubble dissolving apparatus according to claim 2, wherein the partition walls (15a, 15c) become smaller in slit as the upper portion of the barrier ribs (15a, 15c) rises upward from the lower part of the impeller (13, 14) for generating fine bubbles.