KR20030021664A - Ozonizer producing High Concentration Ozone - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone generating apparatus, which aims to generate ozone at a high concentration by cooling the discharge reactor efficiently.

A tubular internal electrode made of metal, a tubular dielectric completely in contact with the internal electrode by an adhesive, a spring type external electrode installed to be kept at a predetermined distance from the internal electrode, and a double tube type external contact with the external electrode. An ozone generator including a cooling tube, characterized by cooling the gas (discharge space) flowing between the dielectric and the external electrode by passing the cooling water through the external cooling tube surrounding the tubular inner electrode and the outer electrode.

Description

Ozonizer producing High Concentration Ozone

The present invention relates to an ozone generator, and more particularly, to a high concentration ozone generator capable of generating ozone at a high concentration by cooling the discharge space efficiently.

Ozone is the strongest oxidizing material except F ₂ , F ₂ O and O · (oxygen radicals) among oxidizing agents. It can be used for sterilization, deodorization, decolorization or bleaching because it can oxidize almost all organic materials.

When ozone is generated in a small amount, ultraviolet irradiation or electrolysis may be used. However, when ozone is generated in a high concentration or in a large amount, it is generally caused by an electrical discharge.

In the case of electrical discharge, barrier discharge is usually performed. In Korean Patent Laid-Open Nos. 2001-5441, 2000-30121, 1999-31892, and 1998-81118, glass electrodes or ceramic dielectrics are interposed between metal electrodes on both sides. An ozone generator in the form of a phase is disclosed, and Korean Laid-Open Patent Publications 2001-15789, 2000-61577, 2000-58938, 2000-58453, 1999-68473, and 2000-46786 disclose a thin film of metal outside a dielectric such as glass. An ozone generator is disclosed in which a metal wire on a coil or a metal plate is adhered to each other, and a metal wire on a coil is fitted to the inner diameter.

However, in the above inventions, since the electrode is manufactured by coating the inside or the outside of the glass tube with a conductive metal, the electrode must be brought out by contacting the conductor with the metal surface, but the contact between the lead wire and the metal electrode is not completely fixed or weakly fixed. It is a very difficult to handle the device because it may cause the contact failure and the member is inserted in order to keep the gap between the dielectric tube and the metal electrode constant. The disadvantage is that it is beneficial.

In addition, ozone should be cooled because it rapidly decomposes to oxygen when it is 60 ° C. or higher. However, the present invention has a disadvantage in that the cooling efficiency is not good because it cannot directly cool the dielectric surface where the discharge is actually occurring.

In addition, the existing ozone generator has a disadvantage that it is difficult to handle because of the use of glass having a low impact resistance as a dielectric and has a disadvantage in that maintenance and repair are not easy because it is integrally molded.

An object of the present invention is to provide a high concentration ozone generating device having a good cooling efficiency and robust and easy to handle.

1 is an exploded perspective view of the ozone generating device of the present invention.

2 is a cross-sectional view of the ozone generating device of the present invention.

3 is a cross-sectional view taken along line AA ′ of FIG. 2.

Explanation of symbols on the main parts of the drawings

1: internal electrode (internal cooling tube) 2: dielectric

3: adhesive 4: external electrode

5: external cooling conduit 6, 7: cooling water inlet

8, 9: gas entrance 10: plug

11: cylindrical ring 12: O-ring

13: power supply

The ozone generating device of the present invention includes a tubular internal electrode made of metal, a tubular dielectric completely in contact with the internal electrode by an adhesive, a spring type external electrode installed at a constant distance from the internal electrode, and the external electrode. And an external cooling tube having a double tube shape in close contact with each other, and cooling the gas flowing between the dielectric and the external electrode by passing the cooling water through the inside of the tubular inner electrode and the outer cooling tube surrounding the outer electrode.

Compared to the conventional ozone generator using the spring electrode as the internal electrode, the present invention is characterized in that it is used as the external electrode. Thus, the discharge space can be placed on the external electrode side instead of the internal electrode. It can be cooled separately. However, Korean Patent Laid-Open Publication No. 2000-61557 discloses an ozone generating device using a spring as an external electrode, but since it introduces gas toward the external electrode, it is also difficult to effectively cool the external electrode.

Another feature of the present invention is that the outer electrode is in close contact with the outer cooling tube to form a module, and the inner electrode is bonded to the dielectric tube and the adhesive to form another module in a cylindrical ring in which two modules are disposed at both ends. Is maintained at equal intervals.

The spring used as the external electrode is in close contact with the external cooling tube to form a module, unlike the existing ozone generator, so that a separate lead wire is not required, thereby eliminating one of the trouble factors such as poor contact. In addition, since the internal electrode is directly connected to the external cooling tube by the cylindrical ring of insulating material, and the external electrode spring is also installed in close contact with the external cooling tube, the structural stability is excellent, and there is no need to level the installation.

As the dielectric, alumina or zirconia is preferable.

When the ozone generator of the present invention is used by connecting two or more in series, that is, by operating the gas flowing out of one ozone generator into the next ozone generator, high concentration of ozone can be obtained.

The configuration and operation principle of the present invention will be described in detail with reference to FIGS. 1 to 3 showing one embodiment of the present invention.

1 is an exploded perspective view of the ozone generating device of the present invention, FIG. 2 is a sectional view, and FIG. 3 is a sectional view taken along the line A-A 'of FIG.

As shown in Figs. 1 and 2, the ozone generating device of the present invention is basically a metallic tubular internal electrode 1, a tubular dielectric 2 in close contact with the internal electrode, and the internal electrode; It consists of a spring-shaped external electrode (4) installed at regular intervals and an external cooling tube (5) in the form of a double tube in close contact with the external electrode, the internal electrode (1) and the tubular dielectric (2) is a partial discharge In order to prevent it from happening, it is completely sealed by using an adhesive 3 such as epoxy.

If there is a gap between the internal electrode 1 and the dielectric 2, partial discharge occurs and the efficiency of the ozone generator decreases. The conventional ozone generator adopts a method of coating a thin metal film on the tempered glass in order to prevent the occurrence of such a gap, which is accompanied by the problem of connecting the lead wire.

The spring used as the external electrode 4 is made of a corrosion-resistant metal such as stainless, and the spring electrode is tightly fixed to the inside of the external cooling tube 5 to use the entire external cooling tube as the ground electrode. This eliminates the need for a power supply lead and completely solves electrical problems such as poor contact of electrodes, and by using external electrodes in the form of springs, at lower voltages and currents than conventional ozone generators with electrodes using metal thin films on both sides of the dielectric. There is an advantage that the discharge is easily made.

In general, the shape of the electrode is very important in the electrical discharge because the barrier discharge at normal or higher pressure can reduce the magnitude of the voltage applied as the surface area of one electrode is smaller. In particular, the sharper the surface of the electrode, the more economical it is. For this reason, the ozone generator provides the effect of bending the surface of the electrode by inserting and fixing a spring without using the external cooling tube 5 as the electrode. will be.

As illustrated in FIG. 2, the external cooling pipe 5 is provided with four branch pipes 6, 7, 8, and 9, each of which is an entrance to the gas 8, 9 and the cooling water 6, 7. Used. Cooling water inlet (6,7) is directly connected to the outer wall of the external cooling tube (5) flows the cooling water into the cooling tube and because the external electrode (4) is fixed in close contact with the inner wall of the cooling tube cooling of the external electrode (4) The big advantage is that efficiency can be maximized. The gas inlets 8 and 9 are directly connected to the gas passages by being directly connected to the outside from the inner wall of the external cooling pipe.

As shown in FIG. 3, the ozone generating device of the present invention completely solves the problem of increasing the temperature, which is the biggest problem when generating ozone at a high concentration by cooling both sides of the gas passage where discharge occurs using cooling water.

The spring constituting the external electrode 4 preferably has a thickness of 0.5 to 2 mm in order to minimize the applied voltage, and the distance between the spring lines is preferably 1 to 10 mm. It is possible to adjust the concentration of ozone generated by changing the thickness of the spring and the interval between the lines, and of course, it can also be adjusted by adjusting the outer diameter of the internal electrode (1).

Oxygen or air introduced through one of the gas inlets 8 and 9 is ozonated while passing through the gas passage. A cylindrical ring 11 and an O-ring 12 are installed at both ends of the ozone generator to seal the gas. The cylindrical ring 11 serves to maintain the discharge gap (gap between the dielectric and the external electrode) as well as to seal the gas uniformly. Once the stopper 10 is closed, the ozone generator is in the form of a completely sealed, rigid cylindrical pipe, which is simple in structure and easy to handle because all parts are firmly fixed internally. While ozone generators using glass or spacers are used to maintain the gap between the dielectric and the electrodes, great care has to be taken when transporting or installing them. It also has the advantage of being easy to expand as a module. Conventional ozone generators have to continuously expand the outer case in which the coolant flows in order to expand or stack the discharge tube, while one ozone generator of the present invention is formed as an independent module so that any number can be connected in series or in parallel. In addition, each independent module, as well as the spring (4) and the internal electrode bundle (1, 2, 3) can be replaced freely, easy maintenance and repair.

Both electrodes are connected to an external power supply 13. High voltage direct current, high voltage pulsed direct current, high voltage alternating current, and high voltage high frequency alternating current power can be used as power source.

Hereinafter, the ozone generator performance of the present invention will be described in more detail with reference to Examples.

<Example 1>

A) Specification of the device

1) Inner electrode: Stainless steel tube with outer diameter of 6mm

2) External electrode: stainless steel spring with an outer diameter of 14mm and a length of 200mm (the thickness of the stainless steel wire is 1.2mm and the spring wire is 1.5mm)

3) Thickness of insulator and external electrode: 0.8mm

B) Experimental Conditions

The ozone concentration and the amount of ozone generated per hour were measured for oxygen flows of 3, 5, 10, and 15 L / min while supplying AC power with a voltage of 5 kV and a frequency of 15 kHz. The temperature and flow rate of the cooling water were 25 ° C. and about 1 to 3 L / min, respectively.

C) results

The results are shown in Table 1 below. It can be seen that a maximum ozone concentration of 90 g / Nm ³ (4.2 vol%; 42000 ppm) at an oxygen flow rate of 3 L / min and a maximum yield of 18 g / hr were obtained at an oxygen flow rate of 15 L / min.

division 3 L / min 5 L / min 10 L / min 15 L / min Ozone Concentration (g / Nm ³ ) 90 50 30 25 Yield (g / hr) 16.2 15.0 18.0 22.5

<Example 2>

The same apparatus as in Example 1 was used except that the thickness of the stainless steel wire constituting the external electrode was 0.5 mm, the spacing between the spring wires was 2 mm, and the spacing between the insulator and the external electrode was 1.5 mm. Ozone was generated under the same conditions.

As a result, a maximum ozone concentration of 48 g / Nm ³ (4.2 vol%; 42000 ppm) at an oxygen flow rate of 3 L / min and a maximum yield of 20 g / hr were obtained at an oxygen flow rate of 15 L / min.

<Example 3>

The same apparatus as in Example 2 was used except that the spacing between spring lines was 5 mm, and ozone was generated under the same conditions as in Example 2.

As a result, a maximum yield of 43 g / Nm ³ (4.2 vol%; 42000 ppm) at an oxygen flow rate of 3 L / min and a maximum yield of 17.6 g / hr were obtained at an oxygen flow rate of 15 L / min.

According to the present invention, by cooling both sides of the space where the discharge occurs with cooling water, it is possible to effectively prevent the temperature rise and obtain a high concentration of ozone.

The disassembly and assembly of each part is very simple, so it can be easily maintained and repaired. It can be connected in parallel or in series to obtain ozone at the desired concentration and flow rate.

Claims (4)

A tubular inner electrode 1 made of metal, a tubular dielectric 2 completely in contact with the inner electrode by an adhesive 3, and a spring-shaped outer electrode 4 provided at a constant distance from the inner electrode. And an external cooling tube 5 having a double tube shape in close contact with the external electrode, An ozone generator, characterized in that for cooling the gas flowing between the dielectric and the external electrode by passing a cooling water inside the tubular internal electrode (1) and the external cooling tube (5) surrounding the external electrode. The method of claim 1, wherein the external electrode (4) is in close contact with the external cooling tube (5) to form a module, the internal electrode (1) is bonded to the dielectric tube (2) with an adhesive to form another module Ozone generator, characterized in that the two modules are maintained at equal intervals by a cylindrical ring (11) disposed at both ends. The ozone generating device according to claim 1, wherein the dielectric (2) is alumina or zirconia. A method for obtaining a high concentration of ozone by connecting two or more ozone generators of claim 1 in series to introduce a gas flowing out of said ozone generator into a next ozone generator.