KR200384152Y1 - a discharge tube of the ozone apparatus - Google Patents

Abstract

 The present invention relates to a discharge tube structure of an ozone generating device used in a semiconductor manufacturing apparatus, and more particularly, to a discharge tube of an ozone generating device which is easy to manufacture and install by disassembling the discharge tube and to allow partial repair in case of damage.

 The constituent means of the discharge tube of the ozone generator according to the present invention includes a cylindrical first quartz tube having a predetermined diameter and a diameter smaller than the diameter of the first quartz tube, and into the first quartz tube. A cylindrical second quartz tube to be inserted and provided to be inserted into one side of the quartz tube to fix the first quartz tube and the second quartz tube, the gap formed between the first quartz tube and the second quartz tube An oxygen inflow flange for introducing oxygen into the quartz tube and inserted into the other side of the quartz tube to fix the first quartz tube and the second quartz tube, the gap being formed between the first quartz tube and the second quartz tube Characterized in that it comprises an ozone discharge flange for emitting the generated ozone.

Description

Discharge tube of the ozone generator

The present invention relates to a discharge tube structure of an ozone generating device used in a semiconductor manufacturing apparatus, and more particularly, to a discharge tube of an ozone generating device which is easy to manufacture and install by disassembling the discharge tube and to allow partial repair in case of damage.

A general ozone generator generates ozone by the action of ionizing and combining oxygen by the applied energy by introducing dry air or oxygen into a discharge tube while a high frequency of high frequency or high frequency is applied between the discharge electrode and the ground electrode.

The structure of the discharge tube of the conventional general ozone generator for generating ozone according to the above operation is as shown in FIG.

As shown in FIG. 1, the discharge tube 10 of the conventional ozone generator is integrally formed with two tubes 1 and 2 having different diameters, and is formed by the two tubes 1 and 2. It consists of an oxygen inlet tube 4 for introducing oxygen into the gap 3 and an ozone discharge tube 5 for discharging ozone generated in the gap 3.

In the structure as described above, when oxygen is introduced through the oxygen input pipe 4 welded to the tube and high voltage is applied, ozone is formed in the gap 3 formed by the tubes 1 and 2. Will exist. The formed ozone is discharged through the ozone discharge pipe (5) is welded to the tube is installed.

The generated ozone has a characteristic that the third oxygen atom of the three oxygen atoms is easily separated due to the weak bonding force and is changed into oxygen. Oxidation power of the modified oxygen is about 5.6 times stronger than chlorine, has no smell or color, and leaves no chemical properties.

The strong oxidizing power of ozone is a corrosive action by oxidation of the ozone generator itself, causing the discharge tube of the ozone generator to be etched to cause deterioration and aging.

By the way, since the discharge tube of the conventional ozone generator is formed in one piece, there is a disadvantage in having an improper structure to repair the damage of some of the discharge tube caused by the degradation and aging as described above.

In addition, the aging and deterioration phenomenon is concentrated in the oxygen inlet tube and ozone discharge tube in the form of a thin glass tube provided in the discharge tube of the ozone generator, in this case because the oxygen inlet tube and ozone discharge tube is integrally coupled to the tube. Not only is it difficult to partially repair and replace, but there is a problem in that the entire discharge tube needs to be replaced for the partial damage.

The present invention was devised to solve the problems of the prior art as described above, a passage for injecting oxygen or discharging ozone while fixing two quartz tubes and two quartz tubes that can be separated from each other in the discharge tube of the ozone generator. It is an object of the present invention to provide a discharge tube of an ozone generator, which can be easily maintained and further extends its service life, if necessary, by configuring a flange provided with a flange.

The constituent means of the discharge tube of the ozone generator according to the present invention proposed to solve the above technical problem is a cylindrical first quartz tube having a predetermined diameter and a diameter smaller than the diameter of the first quartz tube. It has, but is provided to be inserted into one side of the quartz tube in order to fix the second quartz tube of the cylindrical shape inserted into the first quartz tube, the first quartz tube and the second quartz tube, the first quartz An oxygen inflow flange for introducing oxygen into the gap formed between the tube and the second quartz tube, and is inserted into the other side of the quartz tube to fix the first quartz tube and the second quartz tube, the first quartz tube And an ozone exhaust flange for discharging ozone generated in the gap formed between the second quartz tube and the second quartz tube.

In addition, the first quartz tube and the second quartz tube is provided separately from each other, unlike the prior art, it is characterized in that it can be assembled to form a discharge tube and separated as necessary. The first quartz tube and the second quartz tube are configured to apply a high frequency high voltage to each other, including a paint electrode part for acting as an electrode.

In addition, the oxygen inlet flange and the ozone discharge flange, the first contact portion of the cylindrical contacting the outer surface by a predetermined length toward the center from the end of the first quartz tube, the inner surface by a predetermined length toward the center from the end of the second quartz tube A second cylindrical contact portion which is in contact with the first contact portion and an inner surface of the first contact portion and an outer surface of the second contact portion to be fixedly coupled to the first contact portion and the second contact portion, wherein the first quartz tube and the second quartz tube Characterized in that the through hole which can communicate with the gap between the coupling portion is formed in a predetermined portion.

In addition, an O-ring is further provided on an inner surface of the first contact portion and an outer surface of the second contact portion to insert the oxygen inflow flange and the ozone exhaust flange at both ends of the first and second quartz tubes. The gap formed by the first and second quartz tubes is prevented from flowing to the outside.

In addition, a glass tube used as a passage for oxygen or a passage for ozone is inserted into the through-hole to facilitate oxygen inflow and ozone discharge, and to easily replace the aged and deteriorated glass tube. To help.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation and the preferred embodiment of the discharge tube of the ozone generator according to the present invention consisting of the above configuration means.

2 is a schematic view of the discharge tube of the ozone generator according to the present invention, Figure 3 is an exploded perspective view of the discharge tube of the ozone generator.

2 and 3, the discharge tube of the ozone generator according to the present invention is a cylindrical first quartz tube 10 having a predetermined diameter, and a cylindrical second quartz tube inserted into the first quartz tube And the first quartz tube 10 and the second quartz tube 20 to fix the first quartz tube 10 and the second quartz tube 20 and introduce oxygen through the gap 30. In order to fix the oxygen inlet flange 40, the first quartz tube 10 and the second quartz tube 20 is inserted into one side of the) and to discharge ozone present in the gap 30, the first quartz tube 10 and the ozone discharge flange 50 is inserted into the other side of the second quartz tube 20.

The first quartz tube 10 is a long cylindrical tube having a predetermined diameter as one component for forming an assembled discharge tube. The second quartz tube 20 is also a tube having the same shape and length as the first quartz tube 10 as one component for forming an assembled discharge tube.

However, the second quartz tube 20 has a diameter smaller than the first quartz tube 10 by a predetermined length so as to be inserted into the first quartz tube 10. Therefore, when the second quartz tube 20 is inserted into the first quartz tube 10, a gap having a predetermined width generated between an inner surface of the first quartz tube 10 and an outer surface of the second quartz tube 20 ( 30) is formed.

As described above, the first quartz tube 10 and the second quartz tube 20 are provided separately from each other. However, it may be fixedly assembled by the oxygen inlet flange 30 and the ozone inlet flange 40.

On the other hand, the first quartz tube 10 and the second quartz tube 20 is subjected to a high voltage of a high frequency in order to generate ozone from oxygen flowing into the gap 30. Accordingly, the first quartz tube 10 and the second quartz tube 20 preferably have paint (paint and varnish) electrode portions (not shown) which serve as electrodes on the inside and outside. .

The first quartz tube 10 and the second quartz tube 20 are assembled and fixed by an oxygen inflow flange 40 and an ozone exhaust flange 50 of a predetermined shape.

4 is a detailed configuration diagram of the oxygen inlet flange 40 or the ozone discharge flange 50. Since the structure of the oxygen inlet flange 40 and the ozone outlet flange 50 is the same, only the oxygen inlet flange 40 will be described below, the structure and operation of the oxygen inlet flange 40 to the ozone outlet flange 50. Apply.

As shown in FIG. 4, the oxygen inflow flange 40 has a cylindrical second shape having a diameter smaller than a diameter of the first contact portion 41 and the first contact portion 41 having a predetermined length. The first contact portion 41 and the second contact portion 43 are brought into contact with the contact portion 43, the inner surface 41b of the first contact portion 41, and the outer surface 43a of the second contact portion 43. It comprises a coupling portion 45 for fixing.

The first contact portion 41 extends from the end of the first quartz tube 10 toward the center by a predetermined length so that the inner surface 41b contacts the outer surface of the first quartz tube 10. Therefore, the diameter of the cylindrical first contact portion 41 is made slightly larger than the diameter of the first quartz tube 10.

The second contact portion 43 extends from the end of the second quartz tube 20 toward the center by a predetermined length so that the outer surface 43a contacts the inner surface of the second quartz tube 20. Therefore, the diameter of the cylindrical second contact portion 43 is made smaller than the diameter of the second quartz tube 20.

The fixed coupling of the first contact portion 41 and the second contact portion 43 is made through the coupling portion 45. That is, the coupling part 45 is in contact with one side inner surface 41b of the first contact portion 41 and one side outer surface 43a of the second contact portion 43 to contact the first contact portion 41 and the first material. 2 Make sure that the contact portion 43 is fixed. The first and second contact parts 41 and 43 which are in contact with the coupling part 45 may be fixedly coupled by bolting.

The coupling portion 45 has a disc shape with a hollow hole. Therefore, the second contact portion 43 is bolted to the drilled portion 45a, and the disc-shaped coupling part side surface 45b is bolted to the first contact portion 41 to be assembled. have.

On the other hand, the through-hole 47 is formed in a predetermined portion of the disk-shaped coupling portion 45. The through hole 47 is formed in communication with the gap 30 between the first quartz tube 10 and the second quartz tube 20, and the oxygen passes through the through hole 47 to the gap 30. To flow in, and ozone present in the gap 30 may be discharged to the outside.

Into the through-hole 47 formed in the disk-shaped coupling portion 45 by inserting a detachable thin glass tube (70, 80 in Fig. 2) to facilitate the inflow of oxygen into the gap 30, or It is easy to discharge ozone present in the gap 30 to the outside. Since the glass tubes 70 and 80 are detachable at any time, maintenance is easy and can be quickly replaced in case of damage.

Briefly explaining the assembly process of the discharge tube of the ozone generator consisting of a combination of the above configuration means as follows.

The second quartz tube 20 is inserted into the first quartz tube 10 having different diameters once manufactured. In order to fix the first quartz tube 10 and the second quartz tube 20, an oxygen inflow flange 40 is inserted at one side and an ozone discharge flange 50 is inserted at the other side of the first quartz tube ( 10) and the second quartz tube 20 are fixed. The first quartz tube 10 and the oxygen inlet flange 40 and the ozone discharge flange 50 for fixing the first quartz tube 10 and the second quartz tube 20 are assembled in advance. It may be inserted into the second quartz tube 20 or may be assembled while fixing the first quartz tube 10 and the second quartz tube 20.

Meanwhile, in order to maintain the inside and outside airtightness of the gap formed by the first quartz tube and the second quartz tube, the sealing member is formed on the inner surface 41b of the first contact portion 41 and the outer surface 43a of the second contact portion 43. It is preferred to further include an O-ring (80 in FIG. 2).

That is, the O-ring 80 is a sealing member between the inner surface 41b of the first contact portion 41 and the inner surface of the first quartz tube and between the outer surface 43a of the second contact portion 43 and the outer surface of the second quartz tube. Insertion may prevent the oxygen or ozone present in the gap 30 from escaping to the outside, or prevent the outside air from entering the gap 30.

According to the discharge tube of the ozone generator according to the present invention having the configuration and operation and the preferred embodiment as described above, it is easy to repair and easily replace only the damaged part as necessary, since it is composed of an assembly type, it is convenient to maintain There is an advantage.

In addition, when a part is damaged due to aging and deterioration, instead of replacing the entire discharge tube, only the damaged part needs to be replaced, thereby reducing the maintenance cost and extending the service life.

1 is a schematic view of a discharge tube of a conventional ozone generator.

Figure 2 is a schematic diagram of the discharge tube of the ozone generator according to an embodiment of the present invention.

3 is an exploded perspective view of a discharge tube of the ozone generator according to the embodiment of the present invention.

Figure 4 is a detailed view of the oxygen inlet flange and the ozone exhaust flange according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: first quartz tube 20: second quartz tube

30: gap 40: oxygen inflow flange

50: ozone discharge flange 60, 70: glass tube

80: O-ring

Claims (6)

In the discharge tube of the ozone generator, A cylindrical first quartz tube having a predetermined diameter, A cylindrical second quartz tube having a diameter smaller than that of the first quartz tube and inserted into the first quartz tube; An oxygen inflow flange which is provided to be inserted into one side of the quartz tube to fix the first quartz tube and the second quartz tube, and introduces oxygen into a gap formed between the first quartz tube and the second quartz tube; The ozone discharge flange is provided to be inserted into the other side of the quartz tube to fix the first quartz tube and the second quartz tube, and discharges ozone generated in the gap formed between the first quartz tube and the second quartz tube. Discharge tube of the ozone generating device comprising a. The method according to claim 1, The discharge tube of the ozone generator, characterized in that the first quartz tube and the second quartz tube are provided separated from each other. The method according to claim 2, The first quartz tube and the second quartz tube each discharge tube of the ozone generator, characterized in that it comprises a coating electrode portion for acting as an electrode inside and outside. The method of claim 1, wherein the oxygen inlet flange and ozone exhaust flange, A cylindrical first contact portion contacting the outer surface by a predetermined length toward the center at the end of the first quartz tube, a second cylindrical contact portion contacting the inner surface by the predetermined length toward the center at the end of the second quartz tube, and the first contact portion 1 is provided to be in contact with the inner surface of the contact portion and the outer surface of the second contact portion is fixedly coupled to the first contact portion and the second contact portion, the through hole for communicating with the gap between the first quartz tube and the second quartz tube predetermined portion Discharge tube of the ozone generating apparatus comprising a coupling portion formed in the. The method according to claim 4, The discharge tube of the ozone generator, characterized in that the O-ring is further provided on the inner surface of the first contact portion and the outer surface of the second contact portion. The method according to claim 4, Discharge tube of the ozone generator, characterized in that the through-hole is inserted into the glass tube used as the passage for oxygen or the passage for discharging ozone.