JPWO2020213083A1 - Ozone generator and ozone generator set - Google Patents

Abstract

The purpose is to suppress the increase in size of the ozone generator even if the number of discharge units is increased in order to increase the amount of ozone generated. A plurality of columnar discharge units (2) that generate ozone by discharge, a radiator (3) having an insertion hole into which a plurality of discharge units are inserted side by side in a direction orthogonal to the axial direction of the discharge unit, and a radiator. It is an ozone generator (1) provided with a cooler that sends out a cooling medium, and the direction in which the cooler sends out the refrigerant is a direction parallel to the direction in which a plurality of discharge units are arranged.

Description

The present application relates to an ozone generator and an ozone generator set.

Ozone (O ₃₎ has a strong oxidizing power. Ozone is used in a wide range of fields such as water purification, sterilization, sterilization and deodorization in the field of water and sewage treatment, and surface cleaning in the field of semiconductor manufacturing due to its strong oxidizing power. With the recent increase in environmental awareness and the increase in demand for electronic devices, the demand for highly efficient and compact ozone generators is increasing.

As a method of industrially generating ozone, oxygen (O ₂ ) or a raw material gas containing oxygen is passed through a discharge void, an electric field is applied to the discharge void to generate silent discharge, and ozone is generated by this discharge energy. The method is common. In the current ozone generator, about 10% of the input power contributes to ozone generation, and the remaining 90% of the energy is released as heat energy to the discharge void. When the discharge void becomes high temperature due to this thermal energy, the generated ozone is decomposed by heat and the ozone generation efficiency is significantly lowered. Therefore, in the ozone generator, the discharge void is generally cooled by the cooler.

As an ozone generator equipped with a cooler, a plurality of columnar discharge units are arranged in one direction, air-cooled fins in contact with the discharge units are installed, and the direction is orthogonal to the direction in which the plurality of discharge units are arranged in one direction. An ozone generator that cools the discharge unit by blowing cooling air from the direction of cooling has been disclosed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-67464

In order to maintain stable discharge and obtain high ozone generation efficiency, it is advantageous for the columnar discharge unit to have a large specific surface area of the discharge voids. In addition, there is a limit to the amount of ozone generated by one discharge unit. Therefore, when increasing the amount of ozone generated, it is necessary to lengthen the discharge units and increase the number of discharge units arranged side by side. In a conventional ozone generator, cooling air is blown from a direction orthogonal to the direction in which a plurality of discharge units are arranged in one direction to cool the discharge units. Therefore, the number of discharge units is increased in order to increase the amount of ozone generated. It is necessary to increase the area where the cooling air is blown. Therefore, it is necessary to increase the number of coolers as the number of discharge units increases, and there is a problem that the ozone generator becomes large.

The present application has been made to solve the above-mentioned problems, and an object of the present application is to suppress an increase in the size of an ozone generator even when the number of discharge units is increased in order to increase the amount of ozone generated.

The ozone generator of the present application has a plurality of columnar discharge units that generate ozone by discharge, a radiator having an insertion hole into which a plurality of discharge units are inserted side by side in a direction orthogonal to the axial direction of the discharge unit, and heat dissipation. A cooler for delivering ozone for cooling the vessel is provided, and the direction in which the cooler delivers the refrigerant is a direction parallel to the direction in which the plurality of discharge units are arranged.

In the ozone generator of the present application, the direction in which the cooler sends out the refrigerant is parallel to the direction in which a plurality of discharge units are arranged, so that even if the number of discharge units is increased in order to increase the amount of ozone generated, It is possible to suppress the increase in size of the ozone generator.

It is sectional drawing of the ozone generator which concerns on Embodiment 1. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 1. FIG. It is a perspective view of the radiator which concerns on Embodiment 1. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 1. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 2. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 2. FIG. It is a perspective view of the radiator which concerns on Embodiment 2. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 3. FIG. It is sectional drawing of the ozone generator which concerns on Embodiment 3. FIG. It is a schematic diagram of the ozone generator set which concerns on Embodiment 4. FIG.

Hereinafter, the ozone generator and the ozone generator set according to the embodiment for carrying out the present application will be described in detail with reference to the drawings. In each figure, the same reference numerals indicate the same or corresponding parts.

Embodiment 1.
FIG. 1 is a cross-sectional view showing the configuration of the ozone generator according to the first embodiment. In FIG. 1, the ozone generator 1 includes a plurality of cylindrical discharge units 2, a radiator 3 having an insertion hole into which the discharge unit 2 is inserted, and a blower fan 4 as a cooler for cooling the radiator 3. It has. The discharge units 2 are arranged side by side in a direction orthogonal to the axial direction of the discharge unit 2. The blower fan 4 sends out the cooling air W. The direction in which the cooling air W is sent is a direction parallel to the direction in which the discharge units 2 are arranged. The discharge unit 2 includes a ground electrode 10 which is an outer electrode, a dielectric cylinder 11, and a high voltage electrode 12 which is an inner electrode. A discharge gap G is formed between the dielectric cylinder 11 of the discharge unit 2 and the ground electrode 10. Here, the axial direction of the cylindrical discharge unit 2 is the x-axis direction, the direction in which the discharge units 2 are arranged is the y-axis direction, and the directions orthogonal to the x-axis direction and the y-axis direction are the z-axis directions. The cooling air W sent from the blower fan 4 flows in the y-axis direction in the same direction as the direction in which the discharge units 2 are arranged.

FIG. 2 is a cross-sectional view taken from the direction of line AA of FIG. As shown in FIG. 2, the discharge unit 2 includes a ground electrode 10 which is a cylindrical conductive member, and a cylindrical dielectric cylinder 11 having a central axis aligned with the central axis of the ground electrode 10 inside the ground electrode 10. Are arranged concentrically. The dielectric cylinder 11 is supported inside the ground electrode 10 by the spacer 6, and a discharge gap G is formed between the ground electrode 10 and the dielectric cylinder 11. The high voltage electrode 12 is a thin film-shaped conductive member formed on the inner surface of the dielectric cylinder 11. One end of the dielectric cylinder 11 is closed so that gas does not flow inside the dielectric cylinder 11. The other end of the dielectric tube 11 is open to supply a high voltage. The discharge unit 2 is composed of the ground electrode 10, the dielectric cylinder 11, and the high voltage electrode 12. At one end of the discharge unit 2, a header 50 is provided for introducing a raw material gas containing oxygen into the discharge unit 2. Further, the other end of the discharge unit 2 is provided with a header 51 from which the ozone-containing gas containing ozone is derived from the discharge unit 2. In FIG. 2, the arrow 60 indicates the direction of the flow of the raw material gas, and the arrow 61 indicates the direction of the flow of the ozone-containing gas. In FIG. 2, the sending direction of the cooling air W is the direction perpendicular to the paper surface.

The ozone generator 1 includes a plurality of (three in FIG. 1) discharge units 2. Each discharge unit 2 is arranged at equal intervals in the blowing direction of the blowing fan 4. The axial direction of each discharge unit 2 is a direction orthogonal to the blowing direction. Therefore, the axes of the respective discharge units 2 are parallel to each other.

The discharge unit 2 is airtightly configured except for the introduction part and the extraction part of the raw material gas and the ozone-containing gas. A power feeding terminal 41 is inserted into the open end of the dielectric cylinder 11 of the discharge unit 2, and the power feeding terminal 41 is in electrical contact with the high voltage electrode 12. The power supply terminal 41 is connected to the high voltage power supply 40 via an introduction terminal 42 provided in the header 50. The ground terminal of the high voltage power supply 40 is electrically connected so as to have the same potential as the ground electrode 10. A high AC voltage is applied from the high voltage power supply 40 to the high voltage electrode 12 via the power supply terminal 41, and the high voltage of the AC causes discharge in the discharge gap G.

FIG. 3 is a perspective view of the radiator 3. The radiator 3 is provided with three insertion holes 31 arranged in the y-axis direction so that the three discharge units 2 can be arranged side by side in the y-axis direction in which the cooling air W is sent out. The ground electrode 10 of the discharge unit inserted into the insertion hole 31 and the inner wall of the insertion hole 31 are configured to be in contact with each other. Further, the outer peripheral portion of the radiator 3 has fins 21 extending in a direction parallel to the y-axis direction in the direction in which the cooling air W is sent, and grooves 22 formed between the fins 21. The cooling air W sent from the blower fan passes through the groove 22. That is, the direction of the cooling air sent by the blower fan 4 is parallel to the direction in which the plurality of discharge units 2 are arranged.

In the ozone generator of the present embodiment, the ground electrode 10 is made of a conductive material, and it is particularly desirable to use a metal material having excellent corrosion resistance such as stainless steel or titanium. The ground electrode 10 can be made thin as long as its mechanical strength can be maintained, or can be made into a thin film formed on the inner surface of the radiator 3. By making the ground electrode 10 thin or thin, the thermal conductivity in the thickness direction of the ground electrode 10 can be improved, and the cooling performance of the ozone generator 1 can be improved. Further, the surface of the ground electrode 10 exposed to the discharge gap G may be covered with an insulating material having excellent corrosion resistance. By coating the ground electrode 10 with an insulating material having excellent corrosion resistance, a general-purpose conductive material having inferior corrosion resistance can be used for the ground electrode 10, and the manufacturing cost of the ozone generator 1 can be reduced. Can be done. Further, by applying thermal grease, conductive grease, or the like between the ground electrode 10 and the radiator 3, a minute gap between the ground electrode 10 and the radiator 3 can be filled with these greases. As a result, the thermal conductivity between the ground electrode 10 and the radiator 3 can be improved.

The dielectric cylinder 11 is made of an insulating material, and ceramics having excellent corrosion resistance such as quartz, borosilicate glass, and alumina can be used.

The high-voltage electrode 12 is made of a conductive material, and it is particularly desirable that the high-voltage electrode 12 is a conductive thin film formed on the inner surface of the dielectric cylinder 11 by a method such as wet coating, plating, thermal spraying, vacuum deposition, or sputtering. By forming the high-voltage electrode 12 by these methods, the adhesion between the dielectric cylinder 11 and the high-voltage electrode 12 can be improved, and an abnormality occurs between the dielectric cylinder 11 and the high-voltage electrode 12. Discharge can be suppressed. Further, by forming the high voltage electrode 12 with a thin film, the weight of the high voltage electrode 12 can be reduced, and the mechanical strength required for the dielectric cylinder 11 and the spacer 6 can be relaxed.

The power feeding terminal 41 is made of a conductive material, and it is particularly desirable to use a metal material having excellent corrosion resistance such as stainless steel or titanium. The power feeding terminal 41 is electrically connected to the high voltage electrode 12 by a method such as crimping terminal, soldering, or mechanical contact. In particular, by forming the tip of the power supply terminal 41 into a brush shape, when the power supply terminal 41 is inserted into the dielectric cylinder 11, the high voltage electrode 12 and the tip of the brush of the power supply terminal 41 come into contact with each other at a plurality of points. This is preferable because an electrical connection can be reliably secured.

The spacer 6 is made of a conductive material or an insulating material having excellent corrosion resistance. The spacer 6 is provided so as to hold the dielectric cylinder 11 inside the ground electrode 10 so that the width of the discharge gap G becomes substantially constant in the circumferential direction of the discharge unit 2. By making the spacer 6 a tape-shaped part or a spring-shaped part having elasticity in the direction orthogonal to the axis of the discharge unit 2 and arranging the spacers evenly in the circumferential direction of the dielectric cylinder 11, the gap of the discharge gap G can be varied. It can be suppressed.

The gap of the discharge gap G is preferably in the range of 0.1 mm to 10 mm. When the gap of the discharge gap G is 0.1 mm or more, it becomes easy to keep the gap of the discharge gap G uniform in the circumferential direction of the discharge unit 2. Further, when the gap of the discharge gap G is 10 mm or less, it is not necessary to raise the voltage for forming the discharge more than necessary. The gap of the discharge gap G is particularly preferably in the range of 0.2 mm to 0.6 mm. By setting the gap of the discharge gap G in this range, the specific surface area of the discharge gap G can be increased, and the cooling efficiency of the discharge gap G can be improved.

The headers 50 and 51 are made of a conductive material or an insulating material having excellent corrosion resistance. Since it is necessary to make the discharge unit 2 airtight, it is preferable to use stainless steel, fluororesin, or the like having excellent workability for the headers 50 and 51. When a conductive material such as stainless steel is used for the headers 50 and 51, between the high voltage electrodes 12 and the headers 50 and 51 so that no electric discharge is generated between the high voltage electrodes 12 and the headers 50 and 51. It is necessary to secure an insulation distance. When an insulating material such as fluororesin is used for the headers 50 and 51, no discharge is generated between the high voltage electrode 12 and the headers 50 and 51, so that the headers 50 and 51 can be made smaller.

Further, in the ozone generator of the present embodiment, the raw material gas is circulated in one direction from the header 50 to the header 51. Therefore, the ozone generated in the discharge gap G always flows toward the header 51 and does not flow back in the direction of the header 50. Therefore, when ozone is present in the discharge unit 2, the backflow of ozone can be prevented by always circulating the raw material gas in the discharge unit 2, and the header 50, the introduction terminal 42, and the like are corroded by the backflowed ozone. It can be prevented from being done. Further, by preventing the backflow of ozone, a general-purpose material having inferior corrosion resistance can be applied to the header 50, the introduction terminal, and the like, so that the equipment cost can be reduced.

The introduction terminal 42 is a terminal that electrically connects the high voltage power supply 40 and the power supply terminal 41 while maintaining the airtightness inside the header 50. As the introduction terminal 42, for example, a general-purpose voltage introduction terminal composed of a conductor, an insulator, and a packing can be used. The blower fan 4 only needs to be able to create an air flow for cooling the discharge unit 2, and a general-purpose blower such as a propeller fan can be used.

The radiator 3 is made of a material having excellent thermal conductivity, and it is preferable to use a conductive material having excellent thermal conductivity such as aluminum and copper. In particular, by using aluminum which is inexpensive and has excellent workability, the manufacturing cost of the radiator 3 can be reduced.

The raw material gas may contain at least oxygen, and air, oxygen, or a mixed gas of oxygen and an inert gas can be used. As the inert gas, a rare gas, carbon dioxide or the like is used. The pressure of the raw material gas supplied to the discharge gap G is preferably 0.05 MPaG to 0.2 MPaG. If it is 0.05 MPaG or more, ozone is efficiently generated. Further, when it is 0.2 MPaG or less, it is not necessary to raise the discharge pressure of the raw material gas supply device more than necessary. By setting the pressure of the raw material gas to 0.05 MPaG to 0.2 MPaG, the ozone generation efficiency can be economically improved. In addition, even when the size of the ozone generator is increased, by setting it to less than 0.2 MPaG, the ozone generator does not fall under the Type 2 pressure vessel regulations, and legal restrictions are reduced and handling becomes easier. There are also advantages such as.

Next, the basic operation of the ozone generator according to the present embodiment will be described. A raw material gas containing oxygen is introduced into the header 50 from the outside. The raw material gas introduced into the header passes through the discharge gap G formed between the ground electrode 10 and the dielectric cylinder 11, and is led out from the header 51 to the outside. Further, the blower fan 4 is activated, and the cooling air is blown to the radiator 3. After that, the high voltage power supply 40 is operated, and a high voltage of alternating current is applied between the ground electrode 10 and the high voltage electrode 12, and a discharge is formed in the discharge gap G. The electric discharge is uniformly formed between the ground electrode 10 and the high voltage electrode 12 in the circumferential direction and the axial direction of the discharge unit 2. In the process of the raw material gas passing through the discharge void G, oxygen contained in the raw material gas comes into contact with the discharge to generate ozone. Since the discharge unit 2 is a tubular member extending in the direction perpendicular to the paper surface in FIG. 1, the raw material gas is repeatedly exposed to discharge when passing through the discharge gap G, and a large amount of ozone is generated. The heat generated inside the discharge unit 2 due to the discharge is transferred to the radiator 3 by heat conduction and cooled by the cooling air.

Next, the mechanism by which ozone is generated and decomposed by discharge, and the effect of the temperature T of the discharge void G on the generation and decomposition of ozone will be described. When a high AC voltage is applied between the ground electrode 10 and the high voltage electrode 12, the high voltage accelerates the electrons existing in the space of the discharge gap G. At this time, when the oxygen molecule collides with a high-energy electron, the decomposition reaction represented by the equation (1) occurs. Here, e is an electron and O is atomic oxygen.
e + O ₂ → 2O ・ ・ ・ (1)

A part of the atomic oxygen generated by the formula (1) becomes ozone by the reaction represented by the formula (2). Here, M is the third body of the reaction and represents any molecule or atom in the gas.
O + O ₂ + M → O ₃ + M ... (2)

On the other hand, in the discharge gap G, the decomposition reaction of ozone represented by the equations (3) and (4) also occurs at the same time.
O ₃ + M → O ₂ + O + M ... (3)
O ₃ + e → O ₂ + O + e ... (4)
The above is the mechanism by which ozone is generated and decomposed by electric discharge.

Next, the influence of the temperature of the discharge gap G will be described. _{The reaction rate constant k 2 of} Eq. (2) related to ozone production and _{the reaction rate constant k 3} of Eq. (3) related to decomposition are represented by Eqs. (5) and (6), respectively. Here, Ea and Eb are activation energies (positive values) determined by the type of the third body M, respectively.
k ₂ ∝ exp (Ea / T) ・ ・ ・ (5)
k ₃ ∝ exp (-Eb / T) ... (6)

As expressed by the equations (5) and (6), when the temperature T of the discharge gap G increases, k ₂ becomes small and k ₃ becomes large. That is, when the temperature T becomes high, the amount of ozone produced by the reaction represented by the formula (2) decreases, and the amount of ozone decomposed by the reaction represented by the formula (3) increases. Therefore, in order to generate ozone with high efficiency, it is important to keep the temperature of the discharge void G low.

When increasing the amount of ozone generated by the ozone generator, it is necessary to increase the number of discharge units arranged side by side. When cooling air is blown from a direction orthogonal to the direction in which multiple discharge units are arranged in one direction to cool the discharge unit, the area where the cooling air is blown increases as the number of discharge units increases. Need to increase.

On the other hand, in the ozone generator of the present embodiment, the discharge unit is cooled by blowing cooling air from a direction parallel to the direction in which the plurality of discharge units are arranged in one direction. Even if it increases, the area where the cooling air is blown does not expand, only the blowing distance increases. That is, the ozone generator of the present embodiment does not need to increase the number of coolers even when the amount of ozone generated is increased, and it is possible to suppress the increase in size.

In the ozone generator of the present embodiment, one radiator in which a plurality of discharge units are inserted side by side is used, but each of the plurality of discharge units may be provided with an individual radiator. However, in an ozone generator in which each of the plurality of discharge units is provided with an individual radiator, a temperature difference is generated between the radiator located on the upstream side and the radiator located on the downstream side of the cooling air, and the heat sink is located between the plurality of discharge units. A large temperature difference may occur. As a result, the ozone generation efficiency of the discharge unit located on the downstream side may decrease. On the other hand, in the ozone generator provided with one radiator in which a plurality of discharge units are inserted side by side as in the present embodiment, the heat generated by the plurality of discharge units is diffused to the entire radiator through the radiator. Therefore, the temperature difference between the plurality of discharge units becomes small. As a result, it is possible to avoid a decrease in ozone generation efficiency of the discharge unit located on the downstream side.

In the ozone generator of the present embodiment, an example in which a high AC voltage is used for discharge formation has been described, but the power supply applied to the present embodiment does not necessarily have a high AC voltage if a stable discharge can be formed. It does not have to be a voltage power supply, and may be, for example, a pulse power supply.

In addition, the peak value, frequency, duty ratio, etc. of the voltage output from the high-voltage power supply depend on various conditions such as the gap of the discharge gap G, the structure of the discharge unit such as the thickness of the dielectric cylinder, and the composition of the raw material gas. It can be determined as appropriate. Generally, the peak value of the voltage is preferably in the range of 1 kV to 20 kV. If the peak value of the voltage is 1 kV or more, a stable discharge is formed, and if it is 50 kV or less, it is not necessary to increase the size of the power supply and the sophistication of electrical insulation.

Further, the frequency of the voltage output from the high voltage power supply can be appropriately selected from a commercial frequency (several tens of Hz) to an ultra-short wave (several hundreds of MHz). When a commercial frequency voltage is used, the structure of the high-voltage power supply is simplified, adjustments such as electrical matching are facilitated, and manufacturing costs, maintenance costs, etc. can be suppressed. When a high-frequency voltage of several kHz to several 100 MHz is used, charged particles such as electrons generated by the discharge are captured in the discharge void G by the high-frequency AC electric field, and the reaction shown in Eq. (1) can easily proceed. It has the advantage of improving the efficiency of ozone generation.

The fins 21 and the groove 22 of the radiator 3 need only be able to circulate the air blown from the blower fan 4 in the direction orthogonal to the axis of the discharge unit 2, and the fins 21 are inclined with respect to the direction of the blown air of the cooling air W. Alternatively, a through hole, unevenness, or the like may be provided on the side surface of the fin 21. By inclining the cooling air W with respect to the blowing direction or by providing through holes, irregularities, etc. on the side surface of the fin 21, the heat transfer coefficient from the fin 21 to the air is improved, and the ozone generator 1 Cooling performance can be improved. Further, the surface of the radiator 3 may be treated with black coating or black alumite processing. By making the surface of the radiator 3 black, it is possible to promote heat radiation on the surface and improve the cooling performance of the ozone generator 1.

Further, when the radiator 3 is made of a conductive material, the ground electrode 10 and the radiator 3 can be electrically connected to have the same potential. With this configuration, by connecting the ground potential of the high-voltage power supply 40 to the radiator 3, the ground electrode 10 can be set to the same potential as the ground potential of the high-voltage power supply 40. With such a configuration, it is not necessary to directly connect the ground electrode 10 and the high voltage power supply 40, and the configuration of the ozone generator becomes simple.

Further, by forming the radiator 3 with a conductive material having excellent corrosion resistance, the radiator 3 can also serve as the ground electrode 10. FIG. 4 is a cross-sectional view showing the configuration of another ozone generator according to the present embodiment. As shown in FIG. 4, in this ozone generator, the discharge unit 2 includes a radiator 3 that also serves as a ground electrode, a dielectric cylinder 11, and a high voltage electrode 12 that is an inner electrode. A spacer 6 is installed between the radiator 3 of the discharge unit 2 and the dielectric cylinder 11 to form a discharge gap G. In the ozone generator configured in this way, the number of parts is reduced and the manufacturing cost is reduced. Even when a general-purpose conductive material having inferior corrosion resistance is used for the radiator 3, the surface exposed to the discharge void G is covered with an insulating material having excellent corrosion resistance, so that the radiator 3 is used. Can also be used as a ground electrode.

In the present embodiment, a blower fan is used as the cooler and air is used as the refrigerant, but a liquid circulation pump is used as the cooler and a liquid refrigerant such as water or chlorofluorocarbon can be used as the refrigerant. By using a liquid circulation pump as a cooler and using a liquid refrigerant as a refrigerant, the cooling performance of the ozone generator can be further improved. However, as shown in the present embodiment, when the blower fan is used as the cooler and air is used as the refrigerant, the preparation of the refrigerant and the circulation piping are compared with the case where the liquid circulation pump and the liquid refrigerant are used. It becomes unnecessary to make the ozone generator compact, and it is possible to suppress the manufacturing cost and the maintenance cost of the ozone generator.

Embodiment 2.
FIG. 5 is a cross-sectional view showing the configuration of the ozone generator according to the second embodiment. In FIG. 5, the ozone generator 1 sends out a plurality of cylindrical discharge units 2, a radiator 3 having an insertion hole into which the discharge unit 2 is inserted, and a cooling air W for cooling the radiator 3. It is equipped with a fan 4. The ozone generator 1 of the present embodiment includes a heat relaxation unit 23 between the discharge unit 2 and the insertion hole of the radiator 3.
FIG. 6 is a cross-sectional view taken from the direction of line BB of FIG. As shown in FIG. 6, the heat relaxation unit 23 is arranged in contact with the outer peripheral surface of the discharge unit 2 and the inner peripheral surface of the insertion hole of the radiator 3.
FIG. 7 is a perspective view of the radiator 3. The radiator 3 is provided with one insertion hole 31 so that the three discharge units 2 can be arranged side by side in the y-axis direction in the direction in which the cooling air W is sent. Further, a heat relaxation unit 23 having three holes into which the discharge units 2 arranged side by side in the y-axis direction can be inserted is inserted into the insertion holes 31. The heat relaxation unit 23 is arranged in contact with the outer peripheral surface of the discharge unit inserted into the three holes and the inner peripheral surface of the insertion hole 31 of the radiator 3. The heat relaxation unit 23 is made of a material having excellent thermal conductivity, and is particularly preferably made of copper, silver, aluminum, or the like.

As in the first embodiment, the ozone generator configured in this way cools the discharge unit by blowing cooling air from a direction parallel to the direction in which the plurality of discharge units are arranged in one direction. Even if the number of discharge units increases, the area where the cooling air is blown does not expand, only the blowing distance increases. That is, the ozone generator of the present embodiment can suppress the increase in size even when the amount of ozone generated is increased.

Further, in the ozone generator of the present embodiment, since the heat relaxation unit 23 having excellent thermal conductivity is provided so as to be in contact with all the outer peripheral surfaces of the discharge unit 2, the temperatures of all the discharge units 2 are averaged. , It is possible to suppress a decrease in ozone generation efficiency of the discharge unit 2 located on the downstream side. Furthermore, by providing the heat relaxation unit 23 having excellent thermal conductivity, the high thermal conductivity required for the radiator 3 is alleviated, so that the radiator 3 is inferior in thermal conductivity but excellent in corrosion resistance. It will be possible to apply stainless steel, brass with excellent workability, etc.

Embodiment 3.
FIG. 8 is a cross-sectional view showing the configuration of the ozone generator according to the third embodiment. The ozone generator of the present embodiment has a wind tunnel 24 provided in the same configuration as that of the first embodiment. As shown in FIG. 8, the ozone generator 1 of the present embodiment includes a wind tunnel 24 that covers the periphery of the radiator 3. The cooling air W sent from the blower fan flows in the space between the radiator 3 and the wind tunnel 24. The wind tunnel 24 need only have mechanical strength against the wind pressure of the cooling air, and a general-purpose material can be applied.

In the ozone generator configured in this way, the range in which the cooling air W sent from the blower fan flows is limited to the inside of the wind tunnel, so that the airflow in contact with the radiator 3 increases, and the cooling performance of the ozone generator 1 increases. Can be improved.

FIG. 9 is a cross-sectional view showing the configuration of another ozone generator according to the present embodiment. As shown in FIG. 9, the inner wall of the wind tunnel 24 of the ozone generator 1 may be brought into contact with the fins 21 of the radiator 3. In the ozone generator configured in this way, heat conduction is generated from the fins 21 of the radiator 3 to the wind tunnel 24, and the cooling performance of the ozone generator 1 can be further improved. In such a configuration, the wind tunnel 24 is preferably made of aluminum or the like having excellent thermal conductivity.

Embodiment 4.
FIG. 10 is a schematic view showing the configuration of the ozone generator set according to the fourth embodiment. As shown in FIG. 10, in the ozone generator set 70 of the present embodiment, the ozone generator 1 shown in the first to third embodiments is arranged in a direction parallel to the axial direction of the discharge unit and the discharge unit 2. It is provided in four layers in a direction orthogonal to the vertical direction.

In the ozone generator set 70 configured in this way, when the gas pipes are connected and operated in parallel with each ozone generator 1, it is proportional to the number of ozone generators 1 with a small installation area. A large amount of ozone can be generated. Further, when the gas pipes are connected in series to each ozone generator 1 for operation, the raw material gas repeatedly flows through the discharge voids, so that a high concentration of ozone can be obtained with a small installation area of the device. ..

In the ozone generator set 70 of the present embodiment, a high voltage can be applied in parallel to each ozone generator 1 from a single high voltage power source. With such a configuration, the number of high-voltage power supplies can be reduced, and the manufacturing cost and maintenance cost can be reduced. Further, in the ozone generator set 70 of the present embodiment, each ozone generator 1 may be provided with a high voltage power supply. By providing each ozone generator 1 with a high-voltage power supply, the ozone generation amount can be individually adjusted by each ozone generator 1, so that the ozone generation amount as the ozone generator set 70 can be controlled with high accuracy.

Further, in the ozone generator set 70 configured in this way, even if one ozone generator 1 fails, it can be repaired by replacing only the failed ozone generator 1, and the ozone generator set 70 can be repaired. The time required for maintenance can be shortened, and the maintenance cost can be reduced.

Although the present application describes various exemplary embodiments, the various features, embodiments, and functions described in one or more embodiments are limited to the application of the particular embodiment. Rather, it can be applied to embodiments alone or in various combinations.
Therefore, innumerable variations not illustrated are envisioned within the scope of the techniques disclosed in the present application. For example, it is assumed that at least one component is modified, added or omitted, and further, at least one component is extracted and combined with the components of other embodiments.

1 Ozone generator, 2 Discharge unit, 3 Dissipator, 4 Blower fan, 6 Spacer, 10 Ground electrode, 11 Dielectric cylinder, 12 High voltage electrode, 21 Fins, 22 Grooves, 23 Heat relaxation section, 24 Wind tunnel, 40 High Voltage power supply, 41 power supply terminal, 42 introduction terminal, 50, 51 header, 70 ozone generator set.

The ozone generator of the present application has a plurality of columnar discharge units that generate ozone by discharge, and a plurality of insertion holes in which a plurality of discharge units are arranged and inserted in a direction orthogonal to the axial direction of the discharge unit. A radiator and a cooler for delivering ozone for cooling the radiator are provided, and the direction in which the cooler sends out the refrigerant is parallel to the direction in which the plurality of discharge units are arranged.

Claims (8)

Multiple columnar discharge units that generate ozone by discharge, and
A radiator having an insertion hole into which a plurality of the discharge units are inserted side by side in a direction orthogonal to the axial direction of the discharge unit, and a radiator.
An ozone generator including a cooler that sends out a refrigerant that cools the radiator.
An ozone generator characterized in that the direction in which the cooler delivers the refrigerant is a direction parallel to the direction in which the plurality of discharge units are arranged. The ozone generator according to claim 1, further comprising a heat relaxation portion arranged in contact with the outer peripheral surface of the discharge unit and the inner peripheral surface of the insertion hole of the radiator. The ozone generator according to claim 1 or 2, wherein a wind tunnel for confining the refrigerant is provided around the radiator. The ozone generator according to claim 3, wherein a part of the radiator is in contact with the inner peripheral surface of the wind tunnel. The ozone generator according to any one of claims 1 to 4, wherein the radiator is provided with fins and grooves on the outer peripheral portion. The ozone generator according to claim 5, wherein the fins are provided with a plurality of irregularities on the side surface. The ozone generator according to any one of claims 1 to 6, wherein the raw material gas is introduced from one end of the discharge unit, and the ozone-containing gas is derived from the other end. The ozone generator according to any one of claims 1 to 7.
An ozone generator set characterized in that it is provided so as to be stacked in the axial direction of the discharge unit and in a direction orthogonal to the direction in which the discharge units are arranged.

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