KR0144239B1 - Ozonizer - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone generating device, and more particularly, to an ozone generating device that facilitates management of water temperature in a fish farm, an aquarium, and the like, and enables water sterilization and sterilization.

The present invention removes foreign matters from the air introduced by the air pump, removes moisture from the air from which the foreign matters are removed, condenses the refrigerant discharged from the compressor to evaporate the cooled refrigerant, and mixes with the air discharged from the dehumidifier. Ozone is generated by heat dissipation of the mixed refrigerant through the heat sink, and the water stored in the ozone tank is mixed and pumped to maximize the solubility of water and ozone, and dilute and dissolve it to maximize ozone dissolvedness. After dissolving the water-soluble bacteria and foreign matter is supplied to the tank.

Description

Ozone generator

1 is a first embodiment of the ozone generator according to the present invention.

2 is an evaporator piping structure diagram of FIG.

3 is a second embodiment of the ozone apparatus according to the present invention.

4 is a cross-sectional view along the line AA ′ of FIG. 3.

5 is a third embodiment of the ozone generator according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: air pump 2: dust collector filter

3: Dehumidifier 7: Ozone Generator

8: Venturi tube 10: reactor

11: Ozone decomposition filter 24: Anisotropic valve

The present invention relates to an ozone generator, and more particularly, to an ozone generator for facilitating management of water temperature in fish farms and aquariums, and for disinfecting and sterilizing water.

In general, in conventional fish farms and aquariums, there was a device for cooling or heating water for water temperature management, but ozone generation was impossible.

If the aquarium is not cleaned frequently, the minerals are inhibited by the water moss or excreta, which makes it difficult to grow the fish. In the case of fish farms, water disinfection, sterilization, and dirt removal are difficult.

Therefore, in the prior art, the aquarium or fish farms were cleaned manually, and in the case of fish farms, water was disinfected and sterilized by spraying disinfectants.

Because of this, the management of the aquarium or fish farm is inconvenient, of course, there is a problem that the labor cost increases because it depends on manual management.

Therefore, the present invention is to solve various problems such as water temperature management and water disinfection in the conventional fish farms and aquariums as described above, the object of the present invention is to facilitate the management of water temperature by allowing ozone generation in fish farms and aquariums, It is to provide an ozone generating device to enable disinfection and sterilization.

Technical means for achieving the object of the present invention is a dust filter for removing foreign matter from the air introduced by the air pump, a dehumidifier for removing moisture from the air through the dust filter, and the refrigerant discharged from the compressor A condenser for condensation, an evaporator for evaporating the refrigerant cooled in the condenser and mixing the air discharged from the dehumidifier, and an ozone generator for generating ozone by radiating a low temperature refrigerant discharged from the evaporator through a heat sink; A venturi tube that mixes and discharges ozone generated in the ozone generator and water stored in the tank, a pump that pumps ozone water discharged from the venturi tube to maximize the solubility of moles and ozone, and ozone from the ozone water through the pump Dilution and dissolution of the reaction tank to maximize the dissolved ozone, in the reaction tank It is composed of ozone decomposition filter which decomposes water-soluble bacteria and foreign substances from dissolved ozone water and supplies them to the tank.

Another means for achieving the object of the present invention is a dust collecting filter for removing foreign matter from the air introduced through the air pump for introducing air from the outside, a dehumidifier for removing moisture from the air through the dust collecting filter, A condenser for condensing the refrigerant discharged from the compressor, an evaporator for evaporating the refrigerant cooled in the condenser and exchanging the air discharged from the dehumidifier, and a low-temperature refrigerant discharged from the evaporator to radiate heat through a heat sink. Ozone generating means consisting of a heat generating plate cooler for cooling the heat sink with the ozone generator and the cooling air discharged from the evaporator, a check valve for allowing ozone generated in the ozone generator to flow in only one direction, and a fish farm tank A dirt filter for removing foreign substances from stored water, and the check valve Venturi tube for mixing and discharging ozone through and the water through the dirt filter, a pump to maximize the solubility of water and ozone by pumping ozone water discharged from the venturi tube, and ozone from the ozone water through the pump Dilution and dissolution of the reaction tank to maximize the dissolved ozone, and the ozone decomposition filter to decompose the water-soluble bacteria and foreign substances from the ozone water dissolved in the reaction tank and supply to the fish farm tank.

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

FIG. 1 is a first embodiment of the ozone generating apparatus according to the present invention. As shown in FIG. 1, an air pump 1 for introducing air from the outside and a foreign substance from the air introduced by the air pump 1 are shown. A dust collecting filter 2 for removing, a dehumidifier 3 for removing moisture from air through the dust collecting filter 2, a condenser 5 for condensing the refrigerant discharged from the compressor 4, and the condenser ( 5) Evaporator 6 to evaporate the refrigerant cooled in the mixture and discharged by mixing with the air discharged from the dehumidifier (3), and the low-temperature refrigerant discharged from the evaporator (6) through the heat sink to generate ozone By pumping the ozone generator 7, the venturi tube (8) for mixing and discharging the ozone generated in the ozone generator 7 and the water stored in the tank 12, and the ozone water discharged from the venturi tube (8) Pump (9) to maximize the solubility of water and ozone After diluting and dissolving the ozone from the ozone water through the air pump (9) to maximize the dissolved ozone, the reaction tank (10), and decomposing the water-soluble bacteria and foreign matter from the ozone water dissolved in the reaction tank (10) 12) is composed of an ozone decomposition filter (11) for supplying.

Referring to the operation and effects of the first embodiment of the present invention configured as described above are as follows.

First, the air pump 1 sucks air from the outside, and the dust collecting filter 2 removes dust and other foreign substances from the air sucked in this way, and then introduces it into the dehumidifier 3.

The dehumidifier 3 removes more than 90% of the moisture contained in the air by using silica gel from the air introduced by removing foreign substances, and then enters the evaporator 6, and the evaporator 6 heats the introduced air to heat the air. The initial air of the pump 1 is converted into cold air of about 0-5 ° C. and introduced into the compressor 4, which is a cooling system, through the ozone generator 7.

The compressor 4 discharges the refrigerant by the compression operation, the condenser 5 condenses the refrigerant discharged from the compressor 4 to maximize the efficiency of the refrigerant to feed back to the evaporator (6).

The evaporator 6 heat-exchanges the refrigerant to be fed back so that the low-temperature refrigerant flows into the ozone generator 7.

As shown in FIG. 2, the structure of the evaporator 6 is formed as a double porous tube (A: air line, B: refrigerant line), so that air flows into the air line (A) to flow the ozone generator (7). Is introduced into the compressor (4) through the refrigerant flows through the refrigerant pipe (B) to the heat sink of the ozone generator (7).

Accordingly, the ozone generator 7 generates ozone by flowing the low temperature refrigerant flowing into the heat sink, and at this time, cold air flowing through the heat sink through the air pipe a absorbs heat generated when ozone is generated.

On the other hand, ozone generated from the ozone generator (7) is introduced into the venturi tube (8), the venturi tube (8) is mixed with water stored in the tank 12 and the incoming ozone to dilute and dissolve the ozone pump To (9).

At this time, the venturi tube 8 serves to make the flow direction of the mixed ozone water constant.

The pump 9 dilutes and dissolves ozone inflowing ozone water using an impeller to maximize the dissolution efficiency and then flows into the reactor 10.

The pump 9 uses a pump of high efficiency.

The reaction vessel 10 promotes a mixed reaction of ozone and water that is not completely dissolved in the pump 9 to remove the inorganic property present in the water, and also sterilizes bacteria, bacteria, and other foreign substances. To (11).

The ozone decomposition filter 11 removes the odor peculiar to ozone from the incoming ozone water to increase oxygen demand before biochemical chemicals and supply it to the tank 12. In this way, the water stored in the tank can be continuously circulated to maximize the biochemical oxygen demand and to remove foreign substances in the water, thereby enabling optimal water temperature management, cleanliness, and bacteria control in places such as fish farms and aquariums.

3 is a second embodiment of the present invention in which the ozone generating device of the present invention is applied to a fish farm. The air pump 1 and the air pump 1 for introducing air from the outside as shown in FIG. Dust collector (2) for removing foreign matter from the incoming air, dehumidifier (3) consisting of a heater (3a) and silica gel (3b) for removing moisture from the air through the dust filter (2), and a compressor (4) Condenser 5 for condensing the refrigerant discharged from the evaporator, an evaporator 6 for evaporating the refrigerant cooled in the condenser 5 and exchanging the air discharged from the dehumidifier 3, and the evaporator 6 Ozone generator comprising an ozone generator 7a for generating ozone by dissipating a low temperature refrigerant discharged through a heat sink and a heat sink cooler 7b for cooling the heat sink with cooling air discharged from the evaporator 6. 7 and the ozone foot A check valve 16 for allowing ozone generated in the unit 7 to flow in only one direction, a dirt filter 13 for removing foreign substances from the water stored in the fish farm tank 12, and the check valve 16 Venturi tube 13 for mixing and discharging ozone through and the water through the dirt filter 13, and pump (8) for maximizing the solubility of water and ozone by pumping ozone water discharged from the venturi tube (13); , Dilution and dissolution of ozone from ozone water through the pump (8) to maximize ozone dissolution, and decompose water-soluble bacteria and foreign substances from ozone water dissolved in the reaction tank (10) It consists of the ozone decomposition filter 11 which supplies to the tank 12. As shown in FIG.

Referring to the operation and effect of the second embodiment of the present invention configured as described above are as follows.

First, the air pump 1 sucks air at room temperature from the outside and introduces it into the dust collecting filter 2, and the dust collecting filter 2 removes dust, foreign matters, etc. from the incoming air of normal temperature, and then dehumidifiers ( To 3).

The dehumidifier 3 removes about 90% of the moisture from the air flowing into the silica gel 3b and flows it into the evaporator 6.

Meanwhile, the refrigerant discharged from the compressor 4 is condensed at high temperature and high pressure in the condenser 5 to flow into the evaporator 6.

At this time, the condenser 5 discharges heat generated while condensing the refrigerant discharged from the compressor 4 at high temperature and high pressure to the outside.

The evaporator 6 heats and discharges the refrigerant flowing in and the air obtained from the dehumidifier 3.

That is, since the evaporator 6 becomes larger in diameter from a smaller diameter to a larger diameter, the pressure becomes weaker to absorb external heat, and the air obtained from the dehumidifier 3 cools the air cooler 6b to ozone as cold air. It is introduced into the heat sink cooler (7) of the generator 7, the refrigerant is heat-exchanged to enter the ozone generator (7a) through the second valve (15).

Then, the ozone generator 7 generates ozone by flowing the refrigerant flowing into the ozone generator 7a to the heat sink, and at this time, the heat sink is cooled by the heat sink cooler 7 for maximizing ozone generation.

At this time, since the ozone generator is expected to have high efficiency at low temperature and low humidity, it is possible to generate a large amount of ozone in a small unit by cooling the heat sink as described above.

Meanwhile, the low temperature refrigerant flowing through the heat sink cooler 7 absorbs heat generated by the ozone generator while passing through the heat sink, and is circulated to the compressor 4 to be in an initial state.

If this operation is repeated, frost and ice may freeze outside the evaporator 6 by the endothermic action of the evaporator 6, thereby inhibiting cooling and heat dissipation of the ozone generator. The air pump 1 is removed and the operation of the rest of the system is turned off.

Then, the heater 3a in the dehumidifier 3 and the heater 6a in the evaporator 6 are driven to heat frost and ice generated outside the evaporator 6, and then open the first valve 14. The moisture generated in the dehumidifier 3 and the moisture generated in the evaporator 6 are released to the outside.

At this time, since the volume of the air cooler 6b is heated, when the refrigerant is sent to the ozone generator 7, the efficiency of the ozone generator is reduced, so that the heated refrigerant is turned off by the second valve 15. It is prevented from entering the ozone generator.

Meanwhile, as described above, the heater is operated for about 10 to 20 minutes to completely remove moisture from the dehumidifier (3) and the air cooler (6b), and when the dehumidification operation is completed, the entire system is initialized and the evaporator is a cooling system. Air passing through (6) passes through the ozone generator to produce high-efficiency ozone.

The ozone generated in this way is introduced into the venturi tube 8 through the check valve 16, wherein the water discharged from the fish farm tank 12 is removed from the venturi tube 8 through the dirt filter 13. Inflow into the state.

Here, the pipe structure as shown in FIG. 4 is formed at the upper end of the fish farm tank 12 so that the sewage and the waste water are caught and flowed into the waste filter 13 through the pipe line.

Accordingly, the venturi tube 8 mixes the water through the dirt filter 13 and the ozone through the check valve 16 to dilute and dissolve the ozone to flow into the pump 9.

The pump 9 pumps the introduced ozone water into a high-efficiency pump to dilute and dissolve the ozone again and introduce the ozone into the reaction tank 10. The reaction tank 10 receives ozone that is not completely diluted and dissolved in the pump 9. By completely reacting, disinfecting and killing bacteria and inorganic substances to maximize dissolution, it is introduced into the ozone decomposition filter (11).

The ozone decomposition filter 11 decomposes the ozone from the incoming ozone water so that the ozone water of about 0.005 PPM flows into the fish farm tank 12.

At this time, by installing a bubble generator (12a) in the piping of the entire fish farm in the ozone water of 0.005PPM to maximize the dissolved oxygen of the fish farm.

5 is a third exemplary embodiment of the present invention, as shown, a dirt filter 13 for filtering dirt from water discharged from a pipe outlet of an aquarium 23, and an ozone generator for generating ozone (O ₃ ). (17), ozone is diluted and dissolved from the venturi tube (8) which mixes the water obtained by the said dirt filter (13) and ozone obtained through the check valve (16), and the ozone water obtained by the said venturi tube (9). The pump 9 to be diluted, the pump 9 to dilute and dissolve ozone from the ozone water obtained by the pump 9, and the ozone water firstly diluted and dissolved in the pump 9 are sufficiently reacted to completely remove bacteria and inorganic substances. A reactor 10 for disinfecting and killing, an anisotropic valve 24 for separating the ozone water obtained in the reactor 10, a compressor 4 and a condenser 5 for cooling the ozone water obtained in the anisotropic valve 24. ) And the cooler 18, and the anisotropic valve (2) 4) a heater 19 for heating the ozone water obtained in 4), and first and second valves 20, 21 for controlling the flow of cooling water and hot water obtained in the cooler 18 and the heater 19, respectively. ) And an ozone decomposition filter (11) which decomposes ozone from the ozone water obtained by the first and second valves (20, 21) and flows it into the aquarium (23).

Referring to the operation and effect of the third embodiment of the ozone generator according to the present invention configured as described above are as follows.

First, in the water discharged from the pipe outlet of the aquarium 23, the dirt filter 13 is introduced into the venturi tube 8 to remove the foreign matter.

On the other hand, the ozone generator 17 generates ozone of an appropriate capacity and flows into the venturi tube 8 through the check valve 16.

Accordingly, the venturi tube 8 mixes the inflowing ozone and water into the pump 9, and the pump 9 dilutes and dissolves the ozone water using a high efficiency pump to maximize ozone dissolution. Inflow to (10).

The reaction vessel 10 re-reacts ozone that is completely diluted and not dissolved in the pump 9 for a predetermined time to completely disinfect and kill bacteria and inorganic substances, and then transfers to the anisotropic valve 24.

Anisotropic valve 24 forms a two-way channel of the incoming ozone water.

The ozone water flowing out into the single channel of the anisotropic valve 24 flows into the warmer 19 and into the cooler 18 of the ozone water flowing out of the other channel.

Then, the refrigerant discharged from the compressor 4 is condensed through the condenser 5 and then evaporated in the cooler 18 to cool the ozone water and flow into the second valve 21, and the heater 19 is internal. The ozone water is heated by the heater of the first valve 20 to be introduced.

At this time, the control device (not shown in the drawing) appropriately controls the above-described first and second valves 20 and 21 according to the set temperature value of the temperature controller 22 inserted into the aquarium 22 to adjust the water temperature. Will be adjusted.

The cooling water or hot water discharged in this manner is input to the ozone decomposition filter 11. Accordingly, the ozone decomposition filter 11 decomposes the ozone from the incoming ozone water to reduce ozone to 0.001 PPM or less, which is an appropriate amount of ozone in the aquarium. Decomposes to be introduced into the aquarium (23).

Here, the warmer 19 can be adjusted to control the anisotropic valve 24 so that the ozone water obtained from the reaction tank 10 flows only to the warmer 19 when there are refractory fishes, whereby warm ozone water flows into the aquarium. will be.

As described above, the present invention is introduced into the aquarium.

As described above, the present invention is capable of generating ozone in an aquarium or fish farm, so that not only biological oxygen requirements can be satisfied, but also bacteria and foreign substances contained in the water can be automatically removed, so that the administrator cleans the aquarium or fish farm manually. It has the effect of solving the problem.

In addition, since the cooling water and hot water can be supplied, water temperature management can be facilitated.

Claims (3)

A dust filter for removing foreign matters from the air introduced by the air pump, a dehumidifier for removing moisture from the air through the dust filter, and a condenser that condenses the refrigerant discharged from the compressor to evaporate and cool the dehumidifier An evaporator that mixes and outputs the air discharged from the air, an ozone generator that generates ozone by radiating heat through a low temperature refrigerant discharged from the evaporator, and a venturi that mixes and discharges ozone generated in the ozone generator and water stored in the tank A pump that pumps the ozone water discharged from the venturi tube and maximizes the solubility of water and ozone, and a reaction tank that maximizes the ozone solubility by diluting and dissolving ozone from the ozone water through the pump. Decomposed water soluble bacteria and foreign substances from dissolved ozone water and supplied to tank Ozone generating apparatus according to claim consisting of the decomposition filter. A dust filter that removes foreign matter from the air introduced by the air pump that introduces air, a dehumidifier that removes moisture from the air through the dust filter, and a refrigerant cooled in a condenser that condenses the refrigerant discharged from the compressor The evaporator to heat and discharge the air discharged from the dehumidifier, and the low temperature refrigerant discharged from the evaporator to radiate heat through a heat sink to cool the heat sink with an ozone generator that generates ozone and cooling air discharged from the evaporator. Water and the check valve through an ozone generating means composed of a heat sink cooler, a check valve for allowing ozone generated in the ozone generator to flow in only one direction, and a dirt filter for removing foreign matter from the water stored in the fish farm tank. A venturi tube for mixing and discharging ozone through the venturi; A pump for maximizing the solubility of water and ozone by pulping ozone water discharged from the water, a reaction tank for maximizing dissolved ozone by diluting and dissolving ozone from ozone water through the pump, and water soluble from ozone water dissolved in the reaction tank. An ozone generating device comprising an ozone decomposition filter for decomposing bacteria and foreign substances and supplying them to a fish farm tank A dirt filter for removing dirt from the water discharged from the pipe outlet of the aquarium, an ozone generator for generating ozone (O ₃ ), a venturi tube for mixing water obtained from the dirt filter, and ozone obtained through a check valve; A pump for diluting and dissolving ozone from ozone water obtained in a venturi tube, a reaction tank for dissolving and killing bacteria and inorganic substances by sufficiently reacting the first dilution and dissolved ozone water in the pump, and for separating ozone water from the reactor. An anisotropic valve, cooling means formed in the anisotropic valve, a heater for heating ozone water obtained in the anisotropic valve, first and second valves for controlling the discharge amount of cooling water and hot water respectively obtained in the cooler and the warmer; And decomposes ozone from ozone water obtained from the first and second valves to the aquarium. An ozone generating device comprising an ozone decomposition filter which is introduced.