KR101044259B1 - Water purifying device - Google Patents

Abstract

The present invention relates to a water purification device, comprising: a water tank in which water is stored; A circulation supply pipe installed in an immersion state in the water stored in the water tank and connected to an underwater pump for pumping water to circulate the pumped water; A first venturi pipe formed at an end of the circulation supply pipe to rapidly change a flow rate of water; It is installed to surround the first venturi tube, the air is sucked from the outside through the inlet pipe installed to be exposed to the outside of the water tank by the pressure difference due to the high flow rate passing through the first venturi tube to mix the air in the water A suction pipe formed to allow; A second venturi tube formed in a middle portion of the suction tube so as to have a smaller diameter and rapidly changing a flow rate of water flowing through the suction tube; An inlet connected to the end of the second venturi tube and an outlet for discharging water to the water tank are formed, and an upper and lower passage intervals between the inlet and the outlet is smaller than the inner diameter of the inlet and the left and right passages The spacing is an ionization passage in which an extension of the inner diameter is formed which is much larger than the inner diameter of the inlet; A plurality of permanent magnets fixed in a plurality of columns horizontally and vertically so as to face the same poles on the upper and lower surfaces of the extension part of the ionization passage;

The invention is characterized in that it comprises a.

Water tanks, submersible pumps, first and second venturi tubes, ionization passages, extensions, permanent magnets

Description

Water purifying device

The present invention relates to a water purification device, and more particularly, is installed in a wastewater treatment tank or aquaculture farms for storing aquatic animals such as prawns, catfish, eel, etc. The present invention relates to a water purification apparatus configured to increase the amount of dissolved oxygen in water by ionizing and generating microbubbles.

Conventional wastewater treatment method is to store the wastewater in a reservoir of a certain size, and to process the first by precipitating impurities, and the second process of the wastewater in which impurities are precipitated again in a filtration tank composed of gravel and sand layer and then add chemicals, etc. The wastewater was treated with wastewater, but this method is inexpensive due to the huge use of construction costs such as massive land and civil works for the construction of reservoirs and filtration tanks, and it takes much time compared to the wastewater treatment capacity, making it inefficient and difficult to repair. It has been pointed out as a disadvantage.

In addition, wastewater treatment facilities such as aeration tanks that treat wastewater by aeration of air also require a large amount of installation cost because they must have various facilities such as a large-scale facility area and microbial attachment members where microorganisms live.

On the other hand, aquaculture farms for farming aquatic animals such as crayfish, catfish and eel are provided with an apparatus for supplying oxygen to the water in order to improve the amount of oxygen remaining in the water. For example, in the case of a shrimp farm, the water droplets sprayed by air are sprayed into the air by contact with air and then back to the water. It is configured to repeat the falling operation to increase the amount of dissolved oxygen in the water. Such aberration device is water that is dissolved in the water in contact with air in the water within the range that can be sprinkled on the surface by sprinkling water by rotating operation. Although the amount of dissolved oxygen can be expected to be improved to some extent in the water around the apparatus, there is a problem that it is difficult to expect the improvement of dissolved oxygen in the water far away from the aberration apparatus. If you do this, the installation cost of the aberration device will increase, Becomes due to the increase in power consumption for operating the car device using expensive power ratio has a disadvantage that the economic burden increases with.

In addition, there is a method of improving the dissolved oxygen amount by blowing air into the water with a blower device using a blower, etc., but the air supplied to the water through the blower device is supplied in a relatively large bubble state and bubbles are rapidly Since there is a problem in that the oxygen of the bubble is not sufficiently dissolved to solve this problem, it is necessary to extend the operating time of the enveloping device to compensate for this, which causes a disadvantage in that power consumption is increased.

The present invention has been proposed in order to solve the problems described in the prior art as described above, in the wastewater treatment tank for treating the wastewater or in aquaculture farms, reservoirs, artificial lakes, ponds, etc. It is installed to suck water into the water pump and to circulate forcedly so that the flow rate of water can be changed quickly by inhaling the air in the water or by inhaling the gas such as oxygen and ozone stored in the gas storage container into the water. It can supply air (oxygen) to the water, and also ionize the molecular structure of the water by the magnetic force of permanent magnets, and at the same time, bubbles generated by the air sucked into the water are finely broken into tiny tiny bubbles to dissolve the dissolved oxygen in the water. Invented for the purpose of providing a water purification apparatus that can increase the improvement of .

The present invention as a means for achieving the above object,

A water tank in which water is stored;

A circulation supply pipe installed in an immersion state in the water stored in the water tank and connected to an underwater pump for pumping water to circulate the pumped water;

A first venturi pipe formed at an end of the circulation supply pipe to rapidly change a flow rate of water;

It is installed to surround the first venturi tube, the air is sucked from the outside through the inlet pipe installed to be exposed to the outside of the water tank by the pressure difference due to the high flow rate passing through the first venturi tube to mix the air in the water A suction pipe formed to allow;

A second venturi tube formed in a middle portion of the suction tube so as to have a smaller diameter and rapidly changing a flow rate of water flowing through the suction tube;

An inlet connected to the end of the second venturi tube and an outlet for discharging water to the water tank are formed, and an upper and lower passage intervals between the inlet and the outlet is smaller than the inner diameter of the inlet and the left and right passages The spacing is an ionization passage in which an extension of the inner diameter is formed which is much larger than the inner diameter of the inlet;

A plurality of permanent magnets fixed in a plurality of columns horizontally and vertically so as to face the same poles on the upper and lower surfaces of the extension part of the ionization passage;

And a control unit.

In addition, a plurality of permanent magnets fixed to face each other on the upper and lower surfaces of the ionization passage in order to generate a resistance to the flow rate of the water to extend the time the water stays in the ionization passage in the expansion portion of the ionization passage It characterized in that it further comprises a plurality of protruding magnets which are fixedly attached so as to protrude from each other in the upper and lower surfaces between them.

In addition, the inlet pipe is connected to one side of the suction pipe is exposed to the outside is characterized in that the gas storage container for storing gas such as oxygen or ozone is connected.

According to the present invention, the water flow rate is rapidly changed by circulating the wastewater stored in the wastewater treatment tank or the water stored in aquaculture farms for storing shrimp, catfish, eel, etc., or by circulating the water stored in a source of water such as reservoirs, artificial lakes, ponds with an underwater pump. Water by inhaling air from the outside, the molecular structure of the water is ionized by the magnetic force of the permanent magnet, and the bubbles generated by the air sucked into the water are finely broken into fine bubbles of very small size to dissolve well in water. It is possible to purify the water quality of waste water by increasing dissolved oxygen in the water stored in the tank or the water of the source, or in the case of aquaculture farms, by increasing the dissolved oxygen in the source, supplying enough oxygen to the treated rivers and fish. It also provides the effect to make it possible, In this case, it provides merit to greatly contribute to water quality improvement.

Specific embodiments of the water purification apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a water purification apparatus for explaining the present invention, and FIG. 2 is a cross-sectional view taken along the line A-A of FIG.

Reference numeral 1 denotes a water tank for storing water such as waste water, and the water tank 1 is a farm for aquatic animals such as lobsters and catfish, or a reservoir where water is stored, such as a reservoir, an artificial lake, a pond, and the like. Include.

The water tank 1 is installed while the submersible pump 2 is immersed in the water, the submersible pump 2 sucks the water stored in the water tank (1) to the circulation supply line (3) Forced circulation through the first end of the circulation supply line 3 is formed with a first venturi tube (4a) for rapidly changing the flow rate of water.

The first venturi tube 4a is installed while being inserted into the suction tube 5, and one side of the suction tube 5 surrounding the outer circumference of the first venturi tube 4a sucks air in the atmosphere. Inlet pipe 51 is installed so as to be exposed to the outside of the water tank (1) to be connected.

A second venturi tube 4b is formed in the suction tube 5 to quickly change the flow velocity of water, and an end of the suction tube 5 extending from the second venturi tube 4b is an ionization passage 6. )

The inlet 61 of the ionization passage 6 is connected to the end of the suction tube 5 extending from the second venturi tube 4b, and the outlet 62 is immersed in the water stored in the water tank 1. It is installed so that the water passing through the ionization passage 6 through the inlet 61 is configured to discharge into the water stored in the water tank (1).

The ionization passage 6 has an expansion portion 63 formed between the inlet 61 and the outlet 62. The expansion portion 63 of the ionization passage 6 has a narrow upper and lower passages and a left and a right passage. The passage is wide. That is, the passage intervals of the upper and lower surfaces 631 and 632 of the expansion part 63 are formed at intervals smaller than the inner diameter of the inlet 61, while the left and right sides 633 of the expansion part 63 are formed. The passage intervals of the 634 are formed at a much larger interval than the inner diameter of the inlet 61, and the upper and lower passages of the outlet 62 of the ionization passage 6 are upper and lower sides of the extension 63. It is smaller than the passage intervals of the 631 and 632, and the left and right passages of the outlet 62 are formed to have the same width as the passage intervals of the left and right sides 633 and 634 of the expansion portion 63.

Upper and lower surfaces 631 and 632 inside the extension 63 of the ionization passage 6 are fixedly attached so as to face the same poles, and are arranged in a plurality of rows in the longitudinal direction so that a repulsive force to push against each other is applied. (7) is formed.

In addition, the upper and lower surfaces 631 and 632 are disposed between the permanent magnets 7 fixed to the ionization passage 6 in a plurality of rows on the upper and lower surfaces 631 and 632 of the expansion part 63. Is attached to protrude to each other to create a resistance to the flow rate of the water flowing through the ionization passage 6 to delay the time that the water passes through the expansion portion 63 and to stay in the expansion portion 63 at the same time A plurality of protruding magnets 71 to be extended is provided.

On the other hand, the inlet pipe 51 connected to one side of the suction pipe 5 to supply oxygen into the suction pipe 5 is installed to be exposed to the atmosphere to suck the air in the atmosphere or the inlet pipe 51 A gas storage container 8 in which gas such as oxygen (0 ₂ ) and ozone (0 ₃ ) is stored is connected, and a valve for controlling the inflow of the gas stored in the gas storage container (8) into the suction pipe (5). 81 is provided.

The operation of the present invention configured as described above will be described.

In order to increase dissolved oxygen by supplying air in the air to the water stored in the water tank (1), the inlet pipe (51) is exposed to the air, and the submerged water is installed in the water stored in the water tank (1). Start the pump (2).

When the submersible pump 2 is operated, the water stored in the water tank 1 is pumped and supplied to the circulation supply line 3 connected to the discharge port through the suction port of the submersible pump. Water forced to circulate to (3) is introduced into the suction pipe (5) in a state in which the flow rate of water is rapidly changed in the process of being discharged to the first venturi pipe (4a), and thus around the first venturi pipe (4a) Since the decompression phenomenon appears, the outside air is introduced into the suction pipe 5 through the inlet pipe 51 exposed to the atmosphere.

As described above, the air introduced into the suction pipe 5 passes through the second venturi pipe 4b together with the water discharged from the first venturi pipe 4a at a high flow rate. The air mixed in the first to be broken into a small size in the process of passing through the second venturi tube 4b in a bubble state, the ionization passage at a high flow rate again in the second venturi tube (4b) The water flowing into the inlet 61 of 6) flows at a slow flow rate when the inner diameter of the left and right sides 633 and 644 is largely expanded, and then flows at a slow flow rate. Permanent magnets 7 which are fixed to the same poles on the upper and lower surfaces 631 and 632 are fixed to each other, so that the water passing through the ionization passage 6 is a permanent magnet. The magnetic force of (7) makes the molecular structure of water active Also, the upper and lower surfaces 631 and 632 have a plurality of protruding magnets 71 projecting alternately between fixed magnets 7 fixedly attached to each other, thus preventing the flow of water. Bubbles mixed in the water flowing into the expansion part 63 through the inlet 61 of 6) and flowing at a slow flow rate are forced to push out of the plurality of permanent magnets 7 arranged to face the same poles. It is discharged into the water stored in the water tank 1 through the outlet 62 in a more finely broken state.

As described above, the water discharged to the outlet 62 of the ionization passage 6 is in a state in which the molecular structure of the water is ionized due to the influence of magnetic forces that the plurality of permanent magnets 7 installed to face each other with the same poles push each other. The fine bubbles contained in the ionized water discharged to the outlet 62 is dissolved in water while staying in the water of the water tank 1 for a long time to increase the dissolved oxygen of the water stored in the water tank 1. .

On the other hand, when it is difficult or difficult to increase the dissolved oxygen amount of the water tank 1 only by the action of sucking the air in the air into the suction pipe (5) to the gas storage container (8) to the inlet pipe (51) of the suction pipe (5). The amount of dissolved oxygen in the water tank 1 can be increased by supplying stored oxygen or ozone.

1 is a schematic view of a water purification apparatus for explaining the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

[Description of Drawings]

1: water tank 2: circulation supply line

3: submersible pump 4a: first venturi tube

4b: second venturi tube 5: suction tube

51: inlet pipe 6: ionization passage

61: entrance 62: exit

63: expansion portion 7: permanent magnet

71: projecting magnet 8: gas storage container

81: valve

Claims (3)

A water tank in which water is stored; A circulation supply pipe installed in an immersed state in the water tank and connected to an underwater pump for pumping water to circulate the pumped water; A first venturi pipe formed at an end of the circulation supply pipe to rapidly change a flow rate of water; It is installed to surround the first venturi tube, the air is sucked from the outside through the inlet pipe installed to be exposed to the outside of the water tank by the pressure difference due to the high flow rate passing through the first venturi tube to mix the air in the water A suction pipe formed to allow; A second venturi tube formed in a middle portion of the suction tube so as to have a smaller diameter and rapidly changing a flow rate of water flowing through the suction tube; An inlet connected to the end of the second venturi tube and an outlet for discharging water to the water tank are formed, and the upper and lower passage intervals between the inlet and the outlet are smaller than the inner diameter of the inlet and are left and right passages. The spacing is an ionization passage in which an extension of an inner diameter larger than the inner diameter of the inlet is formed; In the water purification device comprising: a plurality of permanent magnets fixed in a plurality of rows horizontally and vertically so as to face the same poles on the upper and lower surfaces inside the extension portion of the ionization passage; Between the plurality of permanent magnets fixed to face each other on the upper and lower surfaces of the ionization passage in order to generate a resistance to the flow rate of water in the expansion portion of the ionization passage so as to prolong the time the water stays in the ionization passage. And a plurality of protruding magnets fixedly attached to protrude from each other at upper and lower surfaces thereof. delete The method of claim 1, The inlet pipe is connected to one side of the suction pipe to be exposed to the outside is connected to a gas storage container for storing a gas such as oxygen or ozone.

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