KR101446435B1 - A Sea Water Purifier - Google Patents

Abstract

The present invention relates to a seawater purifier comprising the following: a housing having a space therein; a seawater feeding unit which is formed in a pipe shape, with one end penetrating the top surface of the housing and the other end adjacently formed on the bottom surface of the housing, which includes an ozone lamp therein and has one end where the seawater of an aquarium is fed; an ozone lamp unit which has a first air feeding hole formed to feed air; a compartmentalizing plate which compartments the inside of the housing so as to form a space on the bottom surface of the housing and which has a through-hole on the surface thereof, through which the other end of the ozone lamp unit penetrates; a limestone unit which consists of coral sand and shells loaded on the top surface of the compartmentalizing plate in the space of the housing; a zeolite unit which is loaded on the top surface of the limestone unit in the housing space and which fills the housing; a discharging hole which penetrates through the top surface of the housing and discharges seawater passed through the zeolite; an aeration tank unit which has a space formed on one side of the housing; a connecting unit which connects the discharging hole with the bottom of the aeration tank unit; a second air feeding hole which feeds air through one side of the connecting unit; a gas discharging hole which discharges gas through the top of the aeration tank unit; and a seawater discharging hole which discharges seawater through the side surface of the aeration tank unit. The limestone unit and the zeolite unit are mixed at a weight ratio of 1:9.

Description

{Sea Water Purifier}

The present invention relates to a seawater purifier, and more particularly, to a seawater purifier capable of effectively increasing the survival rate of a live fish by improving the quality of a seawater aquarium.

In mammals, ammonia, which is generated by decomposition of proteins, is converted into urea, which is stored in the kidney, and then discharged out of the body by sweat or urine. In the case of an underwater animal, ammonia is immediately discharged into the urine when ammonia is generated. As a result, it becomes a risk factor for aquatic organisms.

Conventionally, a seawater purifier using an ozone lamp has been manufactured and used. However, a seawater purifier using an ozone lamp can sterilize and deodorize foreign substances contained in the ozone lamp and can alleviate germs. However, There is a problem in that the ammonium ion can not be effectively removed.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above problems, and it is an object of the present invention to provide a seawater purifier capable of sterilizing Escherichia coli and Vibrio in seawater and effectively decomposing ammonium.

Another object of the present invention is to provide a seawater purifier capable of creating an environment in which seawater microorganisms can smoothly operate.

A seawater purifier according to the present invention includes: a housing having a space formed therein; a pipe formed in a pipe shape, one end passing through the upper surface of the housing and the other end adjacent to a bottom surface of the housing; An ozone lamp part having a seawater inlet through which the seawater flows into the aquarium and a first air inlet through which the air is introduced; and an ozone lamp part partitioning the inside of the housing to form a space on the bottom surface of the housing, A lime portion having a through hole formed therein and passing through the other end of the ozone lamp portion; a lime portion having a coral core and a shell portion stacked on the upper surface of the partition plate in the space of the housing; A zeolite part which is filled in the housing and which is passed through the upper surface of the housing to discharge seawater having passed through the zeolite A second air inflow port for injecting air through one side of the connection portion, and a second air inflow port for introducing the air from the first air inflow port to a lower side of the airtight container, And a seawater discharge port through which the seawater is discharged through the side surface of the aeration tank section, wherein the lime section and the zeolite section are mixed at a weight ratio of 1: 9, respectively.

And zeolite particles of the zeolite are pulverized to have a size of 5 to 10 mm.

And a filter portion is further provided in the discharge portion.

And the porosity of the particles of the zeolite part and the particles of the lime part are different from each other.

The seawater purifier according to the present invention has the following effects.

The seawater purifier according to the present invention is capable of sterilizing ozone lamps, promoting the activity of microorganisms removing ammonium by zeolite and lime materials, and discharging nitrate ions generated by the aeration tank to the outside, There is an effect of increasing.

1 is a perspective view showing the structure of a seawater purifier according to the present invention.

Hereinafter, preferred embodiments of the seawater purifier according to the present invention will be described in detail with reference to the accompanying drawings.

1, a seawater purifier according to the present invention comprises a housing 10 having a space formed therein, a pipe 10 having one end penetrating the upper surface of the housing 10, and the other end being connected to the housing 10, An ozone lamp 26 is provided inside the ozone lamp 26 and a seawater inflow port 22 into which the aquarium water flows is formed at one end and a first air inflow port 24 into which air is introduced is formed The ozone lamp unit 20 includes an ozone lamp unit 20 and an ozone lamp unit 20. The ozone lamp unit 20 has a through hole 29 formed in the surface of the housing 10 to define a space on the bottom surface of the housing 10, A lime portion 32 formed of a coral yarn and a shell which are stacked on the upper surface of the partition plate 28 in the space of the housing 10; A zeolite part 34 mounted on the upper surface of the lime part 32 and filling the housing 10, An exhaust port 35 penetrating the upper surface of the housing 10 and discharging seawater having passed through the zeolite 34, an aeration tank 40 formed in a space on one side of the inside of the housing 10, A second air inlet 42 for injecting air through one side of the connecting portion 38 and a second air inlet 42 for connecting the lower portion of the aeration tank 40 to the lower portion of the aeration tank 40. [ And a seawater discharge port 44 for discharging the seawater through the side surface of the aeration tank 40. The gas-

First, a seawater purifier according to the present invention is provided with a housing 10. The housing 10 constitutes the body of the seawater purifier according to the present invention, and a space is provided therein.

An ozone lamp unit 20 is provided inside the housing 10. The ozone lamp part 20 is formed in a pipe shape and has one end penetrating the upper surface of the housing 10 and the other end being a partition plate 28 which will be described more specifically below the bottom surface of the housing 10 Respectively.

The ozone lamp unit 20 includes an ozone lamp 22 and a seawater inlet 22 through which the seawater flows into the airstream and a first air inlet 24 through which the air is introduced . This is to inject air into the seawater passing through the ozone lamp unit 20 so that reaction with ozone can be smoothly performed. The air introduced through the first air inlet 24 may be oxygen.

The ozone lamp 22 of the ozone lamp unit 20 generates a wavelength of 184.9 nm and a wavelength of 253.7 nm. The 184.9 nm wavelength has an effect of generating ozone to sterilize and deodorize the seawater, and the wavelength of 253.7 nm is effective to alleviate bacterial propagation of the seawater.

A partition plate 28 is provided on the bottom surface of the housing 10. The partition plate (28) divides the inside of the housing (10) so that a space is formed on the bottom surface. The other end of the ozone lamp part 20 is formed in the partition plate 28.

A plurality of through holes 29 are formed in the surface of the partition plate 28. This is to allow the seawater, which has passed through the ozone lamp part 20 and has flowed into the lower part of the partition plate 28, to spread evenly to the upper part.

A lime portion 32 is provided in the housing 10. The lime portion 32 may be composed of a coral core and a shell. A zeolite 34 composed of zeolite may be provided on the upper surface of the lime portion 32.

As for the function of the lime portion 32 and the zeolite portion 34, in the case of an underwater animal, when ammonia is generated, the water is directly discharged to the urine so that ammonia (NH ₃ ) reacts with water (H ₂ O) (NH ₄ ⁺ ) and become a risk factor for aquatic organisms.

The zeolite 34 rapidly adsorbs the ammonium ions and converts the ammonium ions into nitrous acid microorganisms into nitrite. Then, the nitrite is decrypted by making the nitro-bacterial microorganism into a more safe nitric acid or nitrate salt.

On the other hand, the zeolite part 34 has a good adsorption ability, but the calcium ion (Ca ²⁺ ) and the magnesium ion (Mg ²⁺ ) in the water are replaced with the sodium ion (Na ⁺ ), Is lowered, thereby causing the above-mentioned underwater microorganisms capable of decomposing the ammonium ion to be added.

In order to prevent this, the calcium carbonate of the lime portion 32 maintains a general hardness (GH), thereby creating an environment in which the above-mentioned underwater microorganisms can smoothly work. The calcium carbonate (CaCO ₃ ) of the lime portion 32 plays a role of maintaining the carbonate hardness (KH) appropriately because it acts as a buffer to prevent a sudden pH change in the aquarium.

The weight ratio of the zeolite portion 34 to the lime portion 32 is preferably 9: 1. This is because when the amount of the zeolite part 34 is larger than the above-mentioned weight ratio, the microorganism becomes a water-resistant state in which the microorganism can not act, and when the amount of the zeolite part 34 is less than the above weight ratio, And the problem of deterioration of the decomposition rate of ammonium ions occurs.

The lime portion 32 and the zeolite portion 34 may be located below the lime portion 32 and the zeolite portion 34 may be located above the zeolite portion 34, The lime portion 32 may be positioned above. Of course, the lime portion 32 and the zeolite portion 34 may be mixed with each other.

In addition, the particles of the lime portion 32 and the zeolite portion 34 may be formed to have different porosity from each other and be mixed with each other at a high density.

The zeolite 34 preferably has a diameter of 5 to 10 mm. This is because if the zeolite particles are larger than 10 mm, the adsorption power of the ammonium ion is lowered. On the other hand, if the particles are smaller than 5 mm, the foreign matter generated after the decomposition of the protein interferes with the flow of water.

A discharge port 35 is provided on the upper surface of the housing 10. The outlet (35) serves to guide the seawater passing through the zeolite (34) through the upper surface of the housing (10) to the outside.

The discharge port 35 is provided with a filter unit 36. The filter unit 36 serves to filter out seawater discharged through the discharge port 35.

An aeration tank 40 is provided on the inner side of the housing 10. The aeration unit 40 serves to discharge nitrate or nitric acid separated from the seawater to the outside.

And a connection portion 38 connecting the discharge port 35 and the downside of the aeration tank 40 is provided. The connection portion 38 is formed in a pipe shape to guide the seawater discharged through the discharge port 35 into the aeration tank 40.

The connecting portion 38 is provided with a second air inlet 42 for injecting air. The second air inlet 42 functions to inject air into the aeration tank 40 to activate nitrate and nitrate gas in the seawater. The air introduced through the second air inlet 42 may be oxygen air.

A gas discharge port (46) is provided above the aeration tank (40). The gas discharge port 46 is vertically formed above the aeration tank 40 and serves to guide the nitric acid or nitrate gas to the outside through the gas discharge port 46.

A seawater discharge port 44 is provided on a side surface of the aeration tank 40. The seawater outlet (44) serves to guide the seawater of the aeration tank (40) to the outside.

Hereinafter, the operation of the seawater purifier according to the present invention will be described in detail.

First, when the seawater flows into the ozone lamp portion 20 through the seawater inlet 22, the air is introduced together through the first air inlet 24. At this time, the seawater is sterilized while passing through the ozone lamp unit 20. The seawater is uniformly injected into the bottom of the housing 10 through the through hole 29 of the partition plate 28.

The seawater is converted into nitric acid or nitrate gas through the lime portion 32 and the zeolite portion 34, and the pH is also kept neutral.

The nitrate and nitrate gas are introduced into the aeration tank 40 through the second air inlet 42 and the nitrate gas and the nitrate gas are introduced into the aeration tank 40 through the gas And is discharged through the discharge port 46. The seawater is discharged through the seawater discharge port 44 and then flows into the aquarium.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

10: housing 20: ozone lamp part
22: seawater inlet 24: first air inlet
26: ozone lamp 28: partition plate
29: through hole 32: lime portion
34: zeolite part 35: outlet
36: filter part 38: connection part
40: aeration tank part 42: second air injection part
44: seawater discharge part 46: gas discharge part

Claims (4)

A housing having a space formed therein;
And an ozone lamp provided inside the ozone lamp. The ozone lamp includes a seawater inlet through which the seawater flows into the aquarium, and an air inlet An ozone lamp unit in which a first air inlet is formed;
A partition plate partitioning the inside of the housing so as to form a space on the bottom surface of the housing, a through hole being formed in the surface, and the other end of the ozone lamp unit passing through;
A lime portion having a coral core and a shell which are stacked on the upper surface of the partition plate in the space of the housing;
A zeolite part mounted on the upper surface of the lime part in the housing space, the zeolite part filling the housing;
A discharge port passing through the upper surface of the housing and discharging seawater having passed through the zeolite;
An aeration tank having a space formed at one side of the inside of the housing;
A connecting portion connecting the discharge port and the lower portion of the aeration tank portion;
A second air inlet for injecting air through one side of the connecting portion;
A gas outlet for discharging gas through the upper portion of the aeration tank;
And a seawater discharge port for discharging seawater through a side surface of the aeration tank section,
Wherein the lime portion and the zeolite portion are mixed at a weight ratio of 1: 9, respectively. The method according to claim 1,
Wherein the zeolite particles of the zeolite are pulverized to a size of 5 to 10 mm. The method according to claim 1,
And a filter portion is further provided at the discharge port. The method according to claim 1,
And the porosity of the particles of the zeolite portion and the particles of the lime portion are different from each other.

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