KR100856863B1 - An ozone generation system - Google Patents

Abstract

An ozone generating system is provided to increase solubility by circulating a portion of ozone water, remarkably reduce heat of high temperatures generated in a process of generating silent electrical discharge using cooling water or refrigerant, and minimize consumption of power and maximize service life of the system by efficiently cooling discharge heat generated during the electrical discharge. An ozone generating system comprises: a power supply part(600) for supplying power; an oxygen generating part(700) for generating oxygen; a water tank(200) for storing and supplying cooling water; a high voltage generating part(610) for receiving a voltage from the power supply part to generate a high voltage; a circulating pump part(300) for mixing cooling water supplied from the water tank with ozone generated from the ozone generating part to discharge the mixture; an ozone generating part(100) which generates ozone by supplying oxygen or air generated from the oxygen generating part into a discharge space and discharging the high voltage received from the high voltage generating part in the discharge space, and which discharges the cooled mixture to the water tank after cooling heat of high temperatures generated in the discharge space with the mixture by receiving the mixture of the ozone and the cooling water discharged from the circulating pump; and a spray pump part(400) for receiving the mixture of the ozone and the cooling water discharged from the ozone generating part to spray and discharge the mixture. The ozone generating system further comprises a dissolving part(500) for receiving the mixture discharged from the circulating pump part or the spray pump part, circulating the mixture to increase solubility of the ozone and cooling water, and discharging the circulated mixture to the ozone generating part.

Description

Ozone Generation System

1 is a conceptual diagram of an ozone generator using a conventional ceramic discharge method

2A and 2B are cross-sectional views and side views of an ozone generator using a conventional silent discharge method.

3 is a block diagram of an ozone generating system according to a first embodiment of the present invention

4 is a block diagram of an ozone generating system according to a second preferred embodiment of the present invention

5 and 6 are exploded perspective and sectional views of the ozone generator used in the present invention

[Description of Major Symbols in Drawings]

100, 1100: ozone generator 110: first electrode tube

111a, 111b: fitting portion 120: dielectric tube

130: heat sink 131: second electrode tube

132: cooling fan

140a, 140b: first and second stopper

141a: cooling inlet 142a: airflow inlet

143a: thread 141b: cooling outlet

142b: Air flow outlet 143b: Female thread

151, 152: O-ring 200, 1200: Tank

300, 1300: circulation pump

400, 1400: injection pump unit

500, 1500: dissolved part 600, 1600: power part

610, 1610: high pressure generator

700, 1700: oxygen generator

The present invention relates to an ozone generating system, and more particularly, to an ozone generating system capable of effectively cooling heat generated during an electrical discharge process for ozone (O ₃ ) generation through a cooling passage to improve ozone generating efficiency.

Today, as the field of use of ozone (O ₃ ) increases day by day, a lot of research on the apparatus or method for generating ozone (O ₃ ) has been made. As a method of generating ozone (O ₃ ), there are a ceramic discharge method, an silent discharge method, an electrolytic method, a photochemical reaction method, a radiation method, and a high frequency electric field method. Among these, the silent discharge method is widely used because it is most excellent in terms of energy efficiency, safety of performance, and simplicity of operation and control.

The conventional ozone generator using the ceramic discharge method, as shown in Figure 1, the power supply unit 10 for supplying power, the oscillation unit 11 for oscillating with the power supplied from the power supply unit 10, and A high pressure generator 12 for generating a high pressure by boosting the voltage supplied from the power supply unit 10 to a high pressure, and an electrode 14 made of a sintered metal are coated on both sides of the ceramic plate 13, and the high pressure generator 12 It is composed of an ozone generating unit 15 for generating ozone (O ₃ ) at a high pressure generated from the.

In the ceramic discharge type ozone generator using the sintered metal as described above, the power supply unit 10 supplies a voltage required for high voltage generation, and the oscillation unit 11 oscillates with the power supplied from the power supply unit 10 to generate an oscillation frequency. In addition, the high pressure generator 12 generates a high pressure of about 3kv or more by applying the voltage supplied from the power supply unit 10 to the ozone generator 15. Accordingly, the ozone generator 15 discharges the sintered metal electrodes 14 formed on both sides of the ceramic plate 13 to generate ozone (O ₃ ).

In addition, the conventional ozone generator using the silent discharge method, as shown in Figs. 2a and 2b, the metal electrode plate 20 to form a first electrode and the outside of the electrode plate 20 surrounding the The quartz tube 21, the metal pipe 23 spaced apart from the quartz tube 21 at a predetermined interval to form the discharge space 22, and the pipe 23 are fixed and generated in the discharge space 22. The heat sink 24 dissipates heat and forms a second electrode.

The conventional ozone generating unit having the above-described structure is made of glass or ceramic between the electrode plate 20 mounted on the inner diameter of the quartz tube 21 serving as the first electrode and the metal electrode of the heat sink 24 serving as the second electrode. When an alternating current or a pulse voltage is applied between the first and second electrodes via a quartz tube 21 as a derivative, an silent discharge is generated between the first and second electrodes, and oxygen or air is supplied to the discharge space 22. While passing through it produces ozone (O ₃ ).

However, the ozone generating unit of the silent discharge type of the conventional ozone generating apparatus has a problem in that ozone generation is disturbed because high heat is generated in the process of generating the silent discharge in the discharge space between the first and second electrodes.

In addition, since an induction tube such as glass or ceramic must be separately configured between the first electrode and the second electrode, there is a problem in that it may be damaged and expensive manufacturing costs are required. In addition, the second electrode has a heat dissipation effect when ozone is generated, but corrosion by ozone proceeds rapidly through metal pipes, thereby reducing the lifespan.

Accordingly, the present invention has been made to solve the above problems, and a first object of the present invention is to provide an ozone generating system in which ozone (O ₃ ) is circulated in a part of dissolved ozone water to increase the dissolved rate.

In addition, a second object of the present invention can significantly reduce the high heat generated during the process of generating a silent discharge between the first electrode and the second electrode constituting the ozone generator of the silent discharge method using a cooling water or a refrigerant. To provide an ozone generating system.

Further, a third object is the life of and to efficiently cool the room, the heat transfer occurring during the discharge to minimize the power consumed to generate ozone (O _3), and maximize the efficiency of generation of ozone (O ₃₎ ozone generating apparatus of the present invention To provide an ozone generating system that can be used semi-permanently by maximizing

In addition, a fourth object of the present invention is to provide an ozone generating system applied to livestock air purification and odor deodorization.

In addition, a fifth object of the present invention is to provide an ozone generating system applied to pest control and soil disinfection of crops.

In addition, a sixth object of the present invention is to provide an ozone generating system for food applied to pesticide removal and disinfection of fruits and vegetables, and food storage.

In addition, a seventh object of the present invention is to provide a fish ozone generating system applied to sterilization and disinfection of fish reservoirs, freezers and aquariums, aquaculture farms.

Further, an eighth object of the present invention is to provide an industrial ozone generating system applied to dyeing and bleaching.

In addition, a ninth object of the present invention is to provide an industrial ozone generating system applied to plant wastewater treatment, sewage purification and water purification.

Ozone generation system according to the present invention for achieving the above object, the power supply for supplying a voltage; An oxygen generator for generating oxygen (O ₂ ); A water tank for storing and supplying cooling water; A high pressure generator for receiving a voltage from the power supply unit to generate a high pressure; A circulating pump for discharging a mixture of ozone (O ₃₎ generated in the mixture with the ozone generator of the cooling water and ozone (O ₃₎ is supplied from the water tank unit; An injection pump unit configured to receive and discharge a mixture of ozone (O ₃ ) and cooling water discharged from the circulation pump; And supplying oxygen (O ₂ ) or air generated from the oxygen generator to a discharge space and discharging the high pressure received from the high pressure generator to the discharge space to generate ozone (O ₃ ) and to generate the ozone (O ₃ ). And an ozone generating unit receiving the mixture discharged from the injection pump unit and cooling the high heat generated in the discharge space and then discharging the mixture into the water tank.

In addition, the ozone generating system according to the present invention for achieving the above object, the power supply unit for supplying a voltage; An oxygen generator for generating oxygen (O ₂ ); A water tank for storing and supplying cooling water; A high pressure generator for receiving a voltage from the power supply unit to generate a high pressure; A circulation pump unit for mixing and discharging ozone (O ₃ ) generated from the cooling water and the ozone generator from the water tank; Supply oxygen (O ₂ ) or air generated from the oxygen generator to the discharge space and discharge the high pressure received from the high pressure generator to the discharge space to generate ozone (O ₃ ) and discharged from the circulation pump An ozone generator that receives a mixture of (O ₃ ) and cooling water and cools the high heat generated in the discharge space and discharges it to the water tank; And an injection pump unit which receives and discharges a mixture of ozone (O ₃ ) and cooling water discharged from the ozone generator and discharges the mixture.

The ozone generating system may further include a dissolved part configured to receive a mixture discharged from the circulation pump part or the injection pump part to circulate to discharge the ozone (O ₃ ) and cooling water to increase the dissolved rate of the cooling water, and to discharge the ozone generating part. Characterized in that configured.

The ozone generating system further includes a dissolved part that receives the mixture discharged from the ozone generating part or the injection pump part and circulates to discharge the ozone (O ₃ ) and the cooling water to increase the dissolved rate of the cooling water; It is characterized by.

The ozone generating unit forms a first electrode and the first electrode tube flowing a cooling material into the interior space; A dielectric tube spaced apart from the first electrode tube at a predetermined interval to form a discharge space and inducing ozone generation in the discharge space; A heat sink positioned outside the dielectric tube and integrally forming a second electrode tube forming a second electrode, and dissipating heat generated in the discharge space; It is fastened to one side of the second electrode tube and fixedly installed on one side of the first electrode tube and the dielectric tube, the air flow inlet for introducing oxygen (O ₂ ) or air into the discharge space and the first electrode tube A first stopper of non-conductive material having a cooling inlet for introducing the cooling material into the inner space of the first plug; And an airflow outlet and the first electrode fastened to the other side of the second electrode tube to fix the first electrode tube and the other side of the dielectric tube to discharge ozone (O ₃ ) or air from the discharge space. And a second stopper of the non-conductive material having a cooling outlet configured to discharge the cooling material from the inner space of the tube.

The dielectric tube is characterized in that one of the quartz tube, glass tube, ceramic tube.

The first and second stoppers are characterized in that consisting of a Teflon material or a polymer material.

The first and second plugs have the cooling inlet or the cooling outlet formed on one side, and a fixing groove and a female screw portion for fixing the first electrode tube and the dielectric tube, respectively, are formed inside the other side. The air flow inlet or the air flow outlet is characterized in that formed on one side of the outer peripheral surface.

The first and second stoppers are characterized in that the use of the O-ring or packing to maintain the airtight when fixing the first electrode tube and the dielectric tube, respectively.

The heat sink is characterized in that a plurality of cooling fans are integrally formed on the outer circumferential surface of the second electrode tube to dissipate heat generated in the discharge space.

The first electrode tube, the heat sink and the second electrode tube may be any one of gold, silver, copper, aluminum, tin, and zinc or at least two alloys.

The ozone generating system is characterized in that used in the barn for sludge treatment including livestock air purification and odor deodorization, manure, dirt.

The ozone generating system is characterized in that it is used in food storage for pesticide removal and disinfection of fruits and vegetables.

The ozone generating system is used for any one of fish reservoirs, freezers, aquariums, farms for sterilization and disinfection of pathogens.

The ozone generating system is characterized in that it is used in industrial ozone generating system for dyeing and bleaching.

The ozone generating system is characterized in that it is used in industrial ozone generating system for plant wastewater treatment, sewage purification and water purification.

The ozone generating system is characterized in that it is used in a plastic house or farmland for pest control and soil sterilization of crops.

Therefore, ozone (O ₃ ) can increase the dissolved rate by circulating a portion of the dissolved ozone water, and in the process of generating the silent discharge between the first electrode and the second electrode constituting the ozone generator of the silent discharge method. The generated high heat can be significantly reduced by using cooling water or refrigerant.

Hereinafter, an ozone generating system according to the present invention will be described in detail with reference to the accompanying drawings.

First embodiment

3 is a configuration diagram of an ozone generating system according to a first embodiment of the present invention.

As shown in FIG. 3, the ozone generating system according to the first exemplary embodiment of the present invention includes an ozone generating unit 100, a water tank 200, a circulation pump unit 300, an injection pump unit 400, and a dissolved part. 500, a power supply unit 600, a high pressure generator 610, an oxygen generator 700, and the like.

The ozone generator 100 supplies oxygen (O ₂ ) or air generated from the oxygen generator 700 to the discharge space and discharges the high pressure received from the high pressure generator 610 to the discharge space to generate ozone. After generating (O ₃ ) and receiving the mixture discharged from the circulation pump unit 300 or the injection pump unit 400, the high heat generated in the discharge space is cooled and then discharged to the water tank 200.

The water tank 200 stores the cooling water discharged through the discharge space of the ozone generator 100.

The circulation pump unit 300 receives the cooling water (H ₂ O) from the water tank 200 and the ozone (O ₃ ) from the ozone generating unit 100, mixes them, and discharges them.

The injection pump unit 400 receives and discharges a mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged from the circulation pump unit 300.

The power supply unit 600 supplies a voltage to the high pressure generator 610, and the high pressure generator 610 boosts the voltage received from the power supply unit 600 to generate a high pressure to the ozone generator 100. Let's do it.

The oxygen generator 700 generates (or supplies) oxygen (O ₂ ) to the ozone generator 100.

On the other hand, the dissolved part 500 is supplied with the mixture (H ₂ O + O ₃ ) discharged from the circulation pump 300 and / or the injection pump 400, the ozone (O ₃ ) and the cooling water ( In order to increase the dissolved rate of H ₂ O) is circulated to discharge to the ozone generating unit (100). The dissolved part 500 having this function is configured to be connected between the output end of the circulation pump 300 and / or the injection pump 400 and the ozone generator 100. However, the dissolved part 500 may not be configured as necessary.

In the ozone generating system according to the above configuration, first, oxygen (O ₂ ) or air is supplied from the oxygen generator 700 to the ozone generator 100, and the ozone generator ( 100) to supply high pressure.

Next, the ozone generator 100 supplies oxygen (O ₂ ) or air generated from the oxygen generator 700 to the discharge space and supplies the high pressure received from the high pressure generator 610 to the discharge space. Discharge generates ozone (O ₃ ). At this time, the ozone generating unit 100 receives the mixture discharged from the circulation pump unit 300 or the injection pump unit 400 to cool the high heat generated in the discharge space and discharge it to the water tank 200. do.

Next, the circulation pump unit 300 receives the cooling water (H ₂ O) from the water tank 200 and the ozone (O ₃ ) from the ozone generating unit 100, mixes them, and discharges them. The injection pump 400 is sprayed by discharging the mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged from the circulation pump unit 300.

Next, the dissolved part 500 receives the mixture (H ₂ O + O ₃ ) discharged from the circulation pump part 300 and / or the injection pump part 400 to receive the ozone (O ₃ ) and cooling water. In order to increase the dissolution rate of (H ₂ O) it is circulated inside and discharged to the ozone generator 100.

The mixture (H ₂ O + O ₃ ) discharged to the ozone generator 100 through the dissolved part 500 cools the high heat generated in the discharge space of the ozone generator 100 and then the water tank 200. Is discharged again.

Second embodiment

4 is a configuration diagram of an ozone generating system according to a second preferred embodiment of the present invention.

As shown in FIG. 4, the ozone generating system according to the second exemplary embodiment of the present invention includes an ozone generating unit 1100, a water tank 1200, a circulation pump unit 1300, an injection pump unit 1400, and a dissolved unit. 1500, a power supply unit 1600, a high pressure generator 1610, an oxygen generator 1700, and the like.

The ozone generator 1100 supplies oxygen (O ₂ ) or air generated from the oxygen generator 1700 to the discharge space, and discharges the high pressure received from the high pressure generator 1610 to the discharge space to generate ozone. After generating (O ₃ ) and receiving a mixture of cooling water (H ₂ O) and ozone (O ₃ ) discharged from the circulation pump unit 1300, the high heat generated in the discharge space is cooled and then discharged.

In this case, the power supply unit 1600 supplies a voltage to the high pressure generating unit 1610, and the high pressure generating unit 1610 boosts the voltage received from the power supply unit 1600 to supply the high pressure to the ozone generating unit 1100. Generates. The oxygen generator 1700 generates (or supplies) oxygen (O ₂ ) to the ozone generator 1100.

The injection pump unit 1400 receives the mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged from the ozone generating unit 1100 and injects the discharge.

The water tank 1200 receives and stores a mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged through the discharge space of the ozone generating unit 1100 and stores the mixture stored in the circulation pump unit 1300. Supply.

The circulation pump unit 1300 receives the supply of ozone (O ₃₎ of from ozone (O ₃₎ as a mixture with the ozone generation unit 100 of the cooling water (H ₂ O) supplied from the water tank 1200, it After mixing, it is supplied to the ozone generator 1100.

On the other hand, the dissolved part 1500 is supplied with the mixture (H ₂ O + O ₃ ) discharged from the ozone generator 1100 and / or the injection pump 1400, the ozone (O ₃ ) and the cooling water ( In order to increase the dissolved rate of H ₂ O) and circulated to discharge to the tank (1200). The dissolved part 1500 having such a function is connected between the output terminal of the ozone generator 1100 and / or the injection pump part 1400 and the water tank 1200. However, the dissolved part 1500 may not be configured as necessary.

In the ozone generating system according to the above configuration, first, oxygen (O ₂ ) or air is supplied from the oxygen generator 1700 to the ozone generator 1100, and the ozone generator ( 1100) to supply high pressure.

Next, the ozone generator 1100 supplies oxygen (O ₂ ) or air generated from the oxygen generator 1700 to the discharge space, and applies the high pressure received from the high pressure generator 1610 to the discharge space. Discharge generates ozone (O ₃ ). At this time, the ozone generator 1100 receives a mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged from the circulation pump unit 1300 and cools and discharges the high heat generated in the discharge space. .

Thereafter, the injection pump unit 1400 receives a mixture of ozone (O ₃ ) and cooling water (H ₂ O) discharged from the ozone generator 1100, and discharges the same by injecting.

Next, the dissolved part 1500 receives the mixture (H ₂ O + O ₃ ) discharged from the ozone generating part 1100 and / or the injection pump part 1400, and supplies the ozone (O ₃ ) and cooling water. In order to increase the dissolution rate of (H ₂ O) it is circulated inside and discharged to the tank (1200).

Next, the water tank 1200 receives and stores a mixture of ozone (O ₃ ) and cooling water (H ₂ O) from the dissolved portion 1500, and stores the stored ozone (O ₃ ) and cooling water (H ₂ O). The mixture is discharged to the circulation pump unit 1300.

Then, the circulation pump unit 1300 in the water tank 1200, ozone (O ₃₎ and the cooling water ozone (O ₃₎ for receiving the supply of a mixture of (H ₂ O) from the ozone generating unit 1100 from the After receiving the mixture, it is discharged to the ozone generator 1100. At this time, the mixture (H ₂ O + O ₃ ) supplied to the ozone generator 1100 is circulated by cooling the high heat generated in the discharge space of the ozone generator 100 and then discharged again.

ozone Generation part

5 and 6 are exploded perspective and sectional views of the ozone generator used in the present invention.

As shown in FIGS. 5 and 6, the ozone generator 100 or 1100 includes a first electrode tube 110, a dielectric tube 120, a heat sink 130, and a first and second teflon stoppers 140a. And 140b).

Here, the first electrode tube 110 is composed of a metal pipe forming the first electrode, the cooling material (cooling water or refrigerant) flows into the inner space of the pipe.

The dielectric tube 120 is composed of a pipe made of one of glass and ceramic materials, including quartz, glass, and ceramics, to induce ozone generation in the discharge space, and the first electrode tube 110 and predetermined The discharge spaces are formed at intervals of.

The heat sink 130 is located outside the dielectric tube 120 and has a plurality of cooling fans 132 formed on an outer circumferential surface of the second electrode tube 131 and the second electrode tube 131 forming a second electrode. ) Is integrally formed and serves to dissipate heat generated in the discharge space.

The first plug 140a is fastened to one side of the second electrode tube 131 to fix the first electrode tube 110 and one side of the dielectric tube 120 to fix the oxygen to the discharge space. (O ₂ ) or a non-conductive material having an air flow inlet 142a for introducing air and a cooling inlet 141a for introducing a cooling material into the inner space of the first electrode tube 110. In addition, a fixing groove and a female screw portion 143a for fixing the first electrode tube 110 and the dielectric tube 120 are formed inside the other side.

The second stopper 140b is fastened to the other side of the second electrode tube 131 to fix the other side of the first electrode tube 110 and the dielectric tube 120 to fix ozone from the discharge space. (O ₃ ) or a non-conductive material in which air flow outlets 142b for discharging air and cooling outlets 141b for discharging the cooling material from the inner space of the first electrode tube 110 are formed. In addition, a fixing groove and a female screw portion 143b for fixing the first electrode tube 110 and the dielectric tube 120 are formed inside the other side.

The first and second stoppers 140a and 140b are fixed by using O-rings 151 and 152 to maintain airtightness when fixing the first electrode tube 110 and the dielectric tube 120. .

Here, the first and second plugs 140a and 140b may be formed using packing instead of the O-rings 151 and 152 to maintain airtightness.

The first and second stoppers 140a and 140b may be made of a Teflon material or a polymer material.

The first electrode tube 110, the heat sink 130, and the second electrode tube 131 may be formed of any one of gold, silver, copper, aluminum, tin, zinc, or at least two alloys. .

Here, the dielectric tube 120 may be formed by coating and coating with powder using an ozone gas generating derivative of a glass material and a ceramic material along the inner diameter of the heat sink 130.

In addition, the heat sink 130 may further install a cooling fan (not shown) outside the heat sink 130 to heat the heat transferred to the cooling fan 132 through the second electrode tube 131. It can also be configured to force cooling.

The ozone generating unit 100 according to the present invention having the above configuration injects oxygen (O ₂ ) or air into the discharge space through the airflow inlet 142a of the first stopper 140a and then the first electrode. When the first electrode is applied to the tube 110 and the second electrode is applied to the second electrode tube 131 of the heat sink 130, the discharge space is formed through the dielectric tube 120 that induces discharge. Ozone (O ₃ ) is generated by the silent discharge at.

For example, when the oxygen supply method is air, the practical ozone concentration range is 13-15 g / m 3, and the power consumption is about 15-18 kW / kg-O ₃ . When the oxygen supply method is pure oxygen (O ₂ ), the practical ozone concentration range is 100-200 g / m 3, and the power consumption is about 7-13 kW / kg-O ₃ .

The principle of generating ozone (O ₃ ) by the silent discharge is represented by the following reaction schemes 1 and 2.

^{_{O 2 + e - ⇒ O +}} O + e -

O + O ₂ + M ⇒ O ₃ + M

That is, the oxygen atoms collided and dissociated by the electrons accelerated by the reaction accelerated by the reaction as shown in Scheme 1 and then react with the oxygen atoms, so that the reaction that dissociates like the reverse reaction of Scheme 2 due to the thermal decomposition of ozone (O ₃ ). do. Therefore, for efficient ozone (O ₃ ) generation, the thermal decomposition of generated ozone (O ₃ ) should be minimized.

In the present invention, in order to efficiently cool the high heat generated during the silent discharge in the discharge space, a coolant (or a refrigerant) is injected into the pipe of the first electrode tube 110 to flow. In this case, since the high heat generated in the discharge space is mostly transmitted through the first electrode tube 110 made of a conductor having a higher thermal conductivity than the dielectric tube 120 installed on the heat sink 130 having the second electrode. The high heat generated in the discharge space may be rapidly cooled by the cooling water (or the refrigerant) flowing in the first electrode tube 110.

Therefore, the ozone generating system of the present invention can quickly cool the high heat generated in the discharge space, thereby further improving the ozone generating efficiency.

The ozone generating system according to the present invention includes air purification and deodorization for livestock, sludge treatment including manure and soil, pest control and soil sterilization of crops, household air purification and odor deodorization, pesticide removal of fruits and vegetables for food, and It is applied to disinfection and food storage, and also to sterilization and disinfection of fish tanks for fish, freezers and aquariums and farms. In addition, it can be used for dyeing and bleaching for industrial purposes, and for industrial wastewater treatment, sewage purification and water purification.

The present invention is not limited to the above-described embodiments, but can be variously modified and changed by those skilled in the art, which should be considered as being included in the spirit and scope of the present invention as defined in the appended claims. will be.

As described above, according to the ozone generating system according to the present invention, the high temperature generated during the process of generating the silent discharge between the first electrode and the second electrode constituting the ozone generating apparatus of the silent discharge method using cooling water or a refrigerant. There is an effect that can be significantly reduced.

In addition, the amount of high heat generated in the discharge space is transmitted through the metal electrode tube having the first electrode more than the amount transferred to the heat sink having the second electrode, so that the coolant or refrigerant flowing inside the electrode tube. There is an effect that can be cooled quickly.

Further, to efficiently cool the room, heat generated during the discharge of ozone (O ₃₎ minimize the power consumed to occur, and ozone (O ₃₎ of the number of semi-permanently used while maximizing production efficiency maximize the life of the ozone generating apparatus It has an effect.

Claims (17)

In the ozone generating system, A power supply unit supplying a voltage; An oxygen generator for generating oxygen (O ₂ ); A water tank for storing and supplying cooling water; A high pressure generator for receiving a voltage from the power supply unit to generate a high pressure; A circulating pump for discharging a mixture of ozone (O ₃₎ generated in the mixture with the ozone generator of the cooling water and ozone (O ₃₎ is supplied from the water tank unit; An injection pump unit configured to receive and discharge a mixture of ozone (O ₃ ) and cooling water discharged from the circulation pump; And Supplying oxygen (O ₂ ) or air generated from the oxygen generator to the discharge space and discharge the high pressure received from the high-pressure generator in the discharge space to generate ozone (O ₃ ) and the circulation pump unit or the injection And an ozone generating unit receiving the mixture discharged from the pump unit and cooling the high heat generated in the discharge space and then discharging it to the water tank. In the ozone generating system, A power supply unit supplying a voltage; An oxygen generator for generating oxygen (O ₂ ); A water tank for storing and supplying cooling water; A high pressure generator for receiving a voltage from the power supply unit to generate a high pressure; A circulation pump unit for mixing and discharging ozone (O ₃ ) generated from the cooling water and the ozone generator from the water tank; Supply oxygen (O ₂ ) or air generated from the oxygen generator to the discharge space and discharge the high pressure received from the high pressure generator to the discharge space to generate ozone (O ₃ ) and discharged from the circulation pump An ozone generator that receives a mixture of (O ₃ ) and cooling water and cools the high heat generated in the discharge space and discharges it to the water tank; And And an injection pump unit configured to receive and discharge a mixture of ozone (O ₃ ) and cooling water discharged from the ozone generator and to discharge the ozone generator. The system of claim 1, wherein the ozone generating system is: And a dissolved part which receives the mixture discharged from the circulation pump part or the injection pump part and circulates to increase the dissolved rate of the ozone (O ₃ ) and the cooling water and discharges it to the ozone generator. Ozone generating system. The system of claim 2, wherein the ozone generating system is: Ozone, characterized in that it further comprises; dissolved in the circulating to receive the mixture discharged from the ozone generator or the injection pump unit to increase the dissolved rate of the ozone (O ₃ ) and the cooling water discharged to the water tank Generation system. The method of claim 1 or 2, wherein the ozone generating unit: A first electrode tube forming a first electrode and flowing a cooling material into the internal space; A dielectric tube spaced apart from the first electrode tube at a predetermined interval to form a discharge space and inducing ozone generation in the discharge space; A heat sink positioned outside the dielectric tube and integrally forming a second electrode tube forming a second electrode, and dissipating heat generated in the discharge space; It is fastened to one side of the second electrode tube and fixedly installed on one side of the first electrode tube and the dielectric tube, the air flow inlet for introducing oxygen (O ₂ ) or air into the discharge space and the first electrode tube A first stopper of non-conductive material having a cooling inlet for introducing the cooling material into the inner space of the first plug; And It is fastened to the other side of the second electrode tube and fixedly installed on the other side of the first electrode tube and the dielectric tube, the air flow outlet for discharging ozone (O ₃ ) or air from the discharge space and the first electrode tube And a second stopper of the non-conductive material having a cooling discharge outlet for discharging the cooling material from the internal space of the ozone generating system. The method of claim 5, wherein The dielectric tube is an ozone generating system, characterized in that one of the quartz tube, glass tube, ceramic tube. The method of claim 5, wherein the first and second stoppers are: Ozone generation system characterized in that consisting of Teflon material or polymer material. The method of claim 5, wherein the first and second stoppers are: The cooling inlet or the cooling outlet is formed on one side, A fixing groove and a female screw portion for fixing the first electrode tube and the dielectric tube, respectively, are formed inside the other side, The airflow inlet or the airflow outlet is formed on one side of the outer peripheral surface ozone generating system. The method of claim 8, wherein the first and second stoppers are: O-ring or packing, respectively, to maintain the airtight when fixing the first electrode tube and the dielectric tube, characterized in that the ozone generating system. The method of claim 5, wherein the heat sink is: And a plurality of cooling fans are integrally formed on an outer circumferential surface of the second electrode tube to dissipate heat generated in the discharge space. The method of claim 5, wherein The first electrode tube, the heat sink and the second electrode tube are: Ozone generating system, characterized in that any one of gold, silver, copper, aluminum, tin, zinc or at least two alloys. The system of claim 5, wherein the ozone generating system is: Livestock Ozone generation system, characterized in that used in livestock house for sludge treatment including air purification and deodorization, manure, dirt. The system of claim 5, wherein the ozone generating system is: Ozone generation system, characterized in that used in food storage for pesticide removal and disinfection of fruits and vegetables. The system of claim 5, wherein the ozone generating system is: Ozone generating system, characterized in that used in any of the fish reservoirs, freezers, aquariums, farms for sterilization and disinfection of pathogens. The system of claim 5, wherein the ozone generating system is: An ozone generating system characterized by being used in an industrial ozone generating system for dyeing and bleaching. The system of claim 5, wherein the ozone generating system is: An ozone generating system characterized by being used in an industrial ozone generating system for plant wastewater treatment, sewage purification and water purification. The system of claim 5, wherein the ozone generating system is: An ozone generating system, characterized in that it is used in a plastic house or farmland for pest control and soil disinfection of crops.

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