KR101425106B1 - Assembly of plasma generating portions for water treating apparatus - Google Patents

Abstract

The purpose of the present invention is to provide an assembly of plasma generating parts of a water treatment apparatus, which has a structure enabling easy coupling of a support head and a dielectric tube and preventing damage to the dielectric tube caused by vibrations or impacts. The assembly of plasma generating parts of a water treatment apparatus comprises the following: a support head including an insertion protruding portion vertically formed at the bottom and an air supply passage vertically formed at a central portion of the insertion protruding portion to be opened at the bottom end of the insertion protruding portion; a discharge electrode vertically installed at a central portion of the air supply passage to be extended below the support head and generate plasma; a dielectric tube having an open top and bottom ends and a vertically standing tube shape, and into which the bottom of the discharge electrode is inserted; and an insulating elastic block including an insertion protruding portion mounting hole in which the insertion protruding portion is fitted, and a dielectric tube mounting hole which is installed below the insertion protruding portion mounting hole to communicate therewith and in which the top end of the dielectric tube is fitted from the bottom, wherein the insertion protruding portion and the top end of the dielectric tube are respectively inserted into the insertion protruding portion mounting hole and the dielectric tube mounting hole to have a predetermined gap therebetween while not being in contact with each other.

Description

Field of the Invention [0001] The present invention relates to a plasma generating subassembly for a water treatment apparatus,

The present invention relates to a plasma generating subassembly of a water treatment apparatus, and more particularly, to a plasma generating subassembly of a water treatment apparatus for generating plasma by generating water from ozone or radicals generated by the generation of plasma, Which is a part of the plasma generating portion.

Recently, studies on a water treatment apparatus using plasma have been actively conducted, and the configuration of a conventional water treatment apparatus using plasma described in Korean Patent Registration No. 10-0924649 is shown in FIG.

1, the water treatment apparatus includes a transparent quartz tube 3 having a long length in the water tank 1 and a quartz tube 3 having an inner diameter and a discharge gap of the quartz tube inserted therein, A mesh type conductive counter electrode 5 for contacting the outer surface of the transparent quartz tube 3 to form a high density plasma region in the conductive discharge electrode 4, An electrode tip which is assembled on the upper end of the quartz tube 3 and fixes the conductive discharge electrode 5 to the central axis of the transparent quartz tube 3 to maintain a gap distance, a head having a gas inlet 6 and a high- (2).

A gas or air is injected into the transparent quartz tube 3 to push water flowing into the transparent quartz tube 3 by the pressure of the injected gas to form a space and shut off the converter, ) And water can be prevented, and at the same time, plasma is generated in the space.

Air or gas passing through the plasma generated region is contacted with the plasma to generate a mixture of H +, O3, radicals, and ions, and such by-products are injected into the water to decompose, oxidize, and remove contaminants contained in the water .

In the conventional water treatment apparatus, a head 2 is formed of an insulating material having a relatively high hardness, and a dielectric tube such as a quartz tube 3 is coupled to a coupling groove formed in the inside of the head. The dielectric tube sandwiched between the coupling grooves was adhered to the head 2 by means of an epoxy or ceramic adhesive 7.

However, when the dielectric tube 3 is damaged due to external impact or burning during use, the upper end of the dielectric tube 3 is bonded to the coupling groove of the head by the adhesive 7, There is a situation in which the operation for replacing or repairing is very difficult.

When water or water containing gas or the like continuously flows into the space between the head 2 and the dielectric tube 3 and moisture begins to adhere to the surfaces of the head 2 and the adhesive 7, The flashover voltage may be lowered and the adhesive or the head 2 may be deteriorated or burned to lead to a fire.

Further, when the adhesive 7 is deteriorated and the insulating material and the dielectric tube 3 can not be fixed, the separation and disconnection of the head 2 and the dielectric tube 3 may occur and induce the generation of normal plasma it's difficult. This causes a problem of dielectric breakdown due to a decrease in dielectric strength between the discharge electrode 4 and the counter electrode 5, insulation breakdown due to tracking phenomenon, and aging of the discharge, thereby lowering the stability of the product.

Vibration due to a plasma impact is continuously generated in the dielectric tube 3 when the plasma is generated to induce fatigue failure in the bonding portion 7 between the head 2 and the dielectric tube 3, If the vibration is continuously transmitted while the dielectric tube 2 and the dielectric tube (quartz tube) are in contact with each other, breakage of the dielectric tube 3 may easily occur.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a water treatment apparatus using plasma, which has a structure capable of preventing the dielectric tube from being damaged by vibration or impact, To provide a plasma generating subassembly.

Another object of the present invention is to provide a plasma generating subassembly of a water treatment apparatus using a plasma having a structure in which a dielectric tube can be easily removed and replaced even when a dielectric tube is broken.

It is another object of the present invention to provide a plasma generating subassembly of a water treatment apparatus having a structure capable of eliminating the risk of burnout or fire by suppressing leakage of current generated on a connection portion between a head and a dielectric tube.

According to an aspect of the present invention, there is provided a plasma generator assembly for a water treatment apparatus, comprising: an insertion protrusion vertically formed at a lower portion of the water generating apparatus; A support head having a supply passage; A discharge electrode installed vertically to the air supply passage and extending to a lower side of the support head to generate plasma; A dielectric tube into which a lower portion of the discharge electrode is inserted, And an insulative elastic block provided below the inserting protrusion mounting hole for inserting the inserting protrusion from the upper side and provided with dielectric capping holes for inserting the upper end of the inserting protrusion mounting hole from the lower side so as to communicate with the inserting protrusion mounting hole, And the insertion projection and the upper end of the dielectric tube are respectively inserted into the insertion projection mounting hole and the dielectric tube construction so as to have a predetermined gap therebetween and are connected to each other in a noncontact state.

Further, the present invention is characterized in that the support head and the dielectric tube are fitted to the insulative elastic block so that the upper end of the dielectric tube is lower than the lower end of the insertion projection, and between the upper end of the dielectric tube and the lower end of the insertion projection And a ceramic insulating tube having an outer diameter smaller than an inner diameter of the air supply passage and the dielectric tube and being attached to the discharge electrode so as to surround the discharge electrode so as to cover the exposure of the discharge electrode.

According to the present invention, the inserting projection and the insulative elastic block are vertically installed in a columnar shape, and the outer peripheral surface of the insulative elastic block is formed along the periphery and includes a plurality of gently curved protrusions each having an annular shape, And a curved path is formed in a path connecting the lower end to the lower end.

Further, the present invention is characterized in that the support head and the dielectric tube are fitted to the insulative elastic block such that the upper end of the dielectric tube is positioned lower than the lower end of the insertion projection, And is arranged so as to cover an area between the lower ends.

In addition, the present invention is characterized in that an annular engaging groove recessed along the circumference is provided between an upper end portion and a lower end portion of the insertion protruding portion, and an inner circumferential surface of the insertion protruding portion is provided with an engaging jaw which is engaged with the engaging groove, And one is located on the outer side where the latching jaw is located.

Further, the present invention is characterized in that the discharge electrode is held in close contact with the inner circumferential surface of the dielectric tube.

According to another aspect of the present invention, there is provided a plasma generating subassembly of a water treatment apparatus comprising: a support plate having an upper plate of a water tank in which a through hole is formed, a discharge pole perpendicularly inserted into the lower portion and extending downward from the insertion protrusion, A dielectric tube in which a top end and a bottom end of the dielectric tube are vertically erected and in which the discharge electrode is inserted; an inserting protrusion mounting hole in which the inserting protrusion is inserted from above; Wherein the inserting projection and the upper end of the dielectric tube are inserted into the inserting projection fitting hole and the dielectric tube fitting in a state of being in contact with each other at a predetermined interval And the inserting projections and the insulative elastic blades The outer peripheral surface of the insulative elastic block is formed along the periphery and has a plurality of annular protuberances so that a curved path is formed along a path connecting the upper and lower ends along the outer surface of the insulative elastic block, The upper end of the insertion protruding portion is in a state of being closely attached to the through hole while the insertion protruding portion is inserted into the penetrating hole of the upper plate and the insertion protruding portion is forced into the opening of the insertion protruding portion.

In addition, in the above-described configuration, the upper end of the insulating elastic block may have an annular ridge protruding outwardly of the diameter of the through hole, and the annular ridge and the ridge may be engaged with the upper surface and the lower surface of the upper plate, Another feature.

The plasma generating subassembly of the water treatment apparatus using plasma according to the present invention has the following effects.

First, since the support head and the dielectric tube are coupled to each other through the insulating elastic block, the support head and the dielectric tube can be easily coupled with each other, and damage to the dielectric tube due to vibration or impact can be prevented. Removal and replacement work of the dielectric tube can be easily performed.

Second, the present invention can eliminate the risk of burnout or fire by suppressing dielectric breakdown and current leakage occurring on the connection portion between the support head and the dielectric tube by providing the ridge portion or the ceramic insulation tube of the insulative elastic block.

Thirdly, the lower part of the discharge electrode is closely contacted with the inner circumferential surface of the dielectric tube, thereby relieving vibration and wobbling, and relieving the fatigue of the connection part between the insulating elastic block and the support head and the connection part between the discharge electrode and the support head.

Fourth, according to the present invention, the upper end of the insulative elastic block is inserted into the through hole of the upper plate of the water tank from below, and the inserting protrusion is pressed against the through hole of the upper plate while being pressed into the inserting protrusion, It can be fixed to the upper plate without using an adhesive. As a result, it is possible to make maintenance and replacement of the apparatus very easy, maintain the sealed state of the water tank, and form a structure free from ozone leaking.

1 is a block diagram of a conventional water treatment apparatus using plasma
2 is a schematic view of a water treatment apparatus equipped with a plasma generating section assembly according to an embodiment of the present invention
3 is an exploded perspective view of a plasma generating subassembly of a water treatment apparatus according to an embodiment of the present invention.
4 is a cross-sectional view of a plasma generator assembly of a water treatment apparatus according to an embodiment of the present invention.
5 is a modification of the plasma generator assembly of the water treatment apparatus according to the embodiment of the present invention.
6 is a perspective view of an insulating elastic block in a plasma generating subassembly of a water treatment apparatus according to another embodiment of the present invention.
7 is an exploded view of a plasma generator assembly of a water treatment apparatus according to another embodiment of the present invention.
8 is a view illustrating an installation state of the plasma generating portion assembly of the water treatment apparatus according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 2 illustrates a water treatment apparatus equipped with a plasma generator subassembly according to an embodiment of the present invention, and FIG. 3 is an exploded perspective view of a plasma generator subassembly of a water treatment apparatus according to an embodiment of the present invention. 4 is a cross-sectional view of a plasma generator assembly of a water treatment apparatus according to an embodiment of the present invention.

2 through 4, the plasma generator assembly of the water treatment apparatus according to an embodiment of the present invention includes an insertion protrusion 11 vertically formed at a lower portion thereof, and an insertion protrusion 11 formed at a lower end of the insertion protrusion 11 A supporting head 10 having an air supply passage 12 vertically formed at a central portion of the projecting portion 11 and a supporting head 10 vertically installed at a center portion of the air supply passage 12, A dielectric tube 30 into which a lower portion of the discharge electrode 20 is inserted and which has a tubular shape in which upper and lower ends are opened and vertically erected; And an insulation elastic block (42) provided at a lower side thereof so as to communicate with the insertion protruding end recess (41) and having a dielectric pipe planting (42) in which the upper end of the dielectric pipe (30) (40) .

The support head 10 includes an insertion protrusion 11 formed with a block-shaped head main body 13 and vertically formed at a lower portion of the head main body 13 and an air supply port 14 Is installed. The insertion protrusion 11 is vertically installed in a cylindrical shape and an air supply passage 12 connected to the air supply port 14 is vertically formed at a central portion of the insertion protrusion 11. The lower end of the air supply passage 12 is opened, The air supplied from the air supply port 14 is discharged from the lower end to be supplied to the dielectric tube 30. [

The support head 10 is a hard material having excellent insulating properties, and is most preferably a ceramic material.

The discharge electrode 20 is connected to the power applying device 82 together with the counter electrode 70 installed in the water outside the dielectric tube 30 to generate plasma in the dielectric tube 30.

The discharge electrode 20 is vertically installed at the center of the air supply passage 12 of the support head 10 and extends to the lower side of the support head 10. The lower portion of the discharge electrode 20 is connected to the dielectric tube 30, . The discharge electrode 20 is vertically installed in the center portion of the air supply passage 12 so that air flows from the periphery of the discharge electrode 20 downward through the air supply passage 12.

The discharge electrode (20) includes a center rod (21) extending vertically and a claw-like support body (22) having a plurality of radially arranged center bars (21). When the lower portion of the discharge electrode 20 is inserted into the dielectric tube 30, since the support body 22 is welded to the center bar 21 and has elasticity, the radially spreading support body 22 contracts due to elasticity, 30 so that the discharge electrode 20 can be supported. Since the generation of the plasma is continuously transmitted to the discharge electrode 20 when the plasma is generated, it is possible to prevent the discharge electrode 20 from vibrating due to the vibration of the discharge electrode 20 when the dielectric tube 30 is in close contact with the inner surface of the dielectric tube 30 and to induce stable plasma generation.

The discharge electrode 20 in which the support member 22 is formed is attached to the inner surface of the dielectric tube 30 to prevent the discharge electrode 20 from shaking. It is also possible to form the discharge electrode 20 in a coherent shape so as to support the discharge electrode 20 without shaking.

The dielectric tube 30 has a tubular shape that is opened vertically at the upper and lower ends and flows vertically through the air supply passage 12 at the upper end thereof. For plasma-reacting air by plasma. The plasma-reacted air is discharged to the water via the porous bubble generator 81 through the open lower end, and reacts with contaminants in the water.

The dielectric tube 30 is most preferably a quartz tube, and a ceramic tube or a glass tube is also possible.

The insulative elastic block 40 is provided to connect the support head 10 and the dielectric tube 30 to each other so that the support head 10 and the dielectric tube 30 are brought into contact with each other Can be connected without being connected.

The insulative elastic block 40 is provided at its upper portion with a protruding protrusion opening 41 for inserting the inserting protrusion 11 of the supporting head 10 from the upper side, A dielectric cap drilling (42) is provided so as to communicate with the protruding damper ground (41) so that the upper end of the dielectric cap (30) is fitted from below.

Since the support head 10 and the dielectric tube 30 are cylindrical in shape, the insertion protruding end constructions 41 and the dielectric tube planting holes 42 are formed as a space having a circumferential inner surface corresponding thereto, It is preferable that the insulating elastic block 40 is also formed in a cylindrical shape.

The insulating elastic block 40 is preferably a silicone resin because it is elastic and has excellent insulation performance so as to absorb a plasma generation impact transmitted to the dielectric tube 30 when plasma is generated, and epoxy resin or rubber material It is possible.

When the support head 10 and the dielectric tube 30 are coupled to the insulation elastic block 40, the insertion protrusion 11 and the upper end of the dielectric tube 30 are separated from each other by a predetermined distance d And is inserted into the insertion protruding portion constructions (41) and the dielectric tube planting (42), respectively, and are connected to each other in a noncontact state.

When the support head 10 and the dielectric tube 30 are directly connected and fixed, the vibration transmitted continuously due to the plasma generation impact is transmitted to the fixed portion to accumulate fatigue, And the dielectric elastic block 40 absorbs the vibration transmitted to the dielectric tube 10 and the dielectric tube 30. In addition, when the support head 10 and the dielectric tube 30 are directly connected and fixed by an adhesive, it is very difficult to separate the adhesion portions of the support head 10 and the dielectric tube 30 from each other, When the insertion protrusion 11 and the dielectric tube 30 are connected to each other in a non-contact state, the dielectric tube 30 can be easily replaced.

Figs. 4 and 5 show a configuration in which the insertion projection 11 and the dielectric tube 30 are connected to each other in a non-contact state.

4, the support head 10 and the dielectric tube 30 are inserted into the insulative elastic block 40 such that the upper end of the dielectric tube 30 is positioned lower than the lower end of the insertion protrusion 11 have.

5, a clearance space 11a having a diameter larger than that of the dielectric tube 30 is formed in the lower portion of the insertion projection 11 of the support head 10 and the clearance 11a of the dielectric tube 30 is formed in the clearance space 11a. And is supported by the insulating elastic block 40 in a state in which the upper end enters but is not in contact with the inner surface of the insertion projection 11. [

When the dielectric tube 30 is inserted into the clearance space 11a in the state where the dielectric tube 30 is inserted into the clearance space 11a, the periphery of the discharge electrode 20 exposed at the coupling portion between the support head 10 and the dielectric tube 30 is inserted into the dielectric tube 30 Since the protrusions 11 are covered together, the risk of current leakage can be minimized.

4, the region where the discharge electrode 20 can not be covered at the coupling portion between the support head 10 and the dielectric tube 30 is located at the lower end of the insertion projection 11 from the upper end of the dielectric tube 30 The ceramic insulated tube 23 is installed to cover the area between the upper end of the dielectric tube 30 and the lower end of the insertion protrusion 11.

The ceramic insulating tube 23 is attached to the discharge electrode 20 so as to surround the discharge electrode so as to cover the exposure of the discharge electrode with an outer diameter smaller than the inner diameter of the air supply passage 12 and the dielectric tube 30, State. Even if the ceramic insulating tube 23 is provided, the flow of air to the outside of the ceramic insulating tube 23 may occur.

6 illustrates an insulation elastic block 400 provided in a plasma generator subassembly of a water treatment apparatus according to another embodiment of the present invention. FIG. 7 illustrates a water treatment apparatus 400 in which such an insulation elastic block 400 is installed Fig. 6 is an exploded view of a plasma generating subassembly; Fig.

The inserting protrusion 110 of the supporting head 100 inserted into the insulative elastic block 400 is also formed in a cylindrical shape and the insulative elastic block 400 is also formed in a cylindrical shape.

However, the insulation elastic block 400 has a plurality of annular protrusions 450, 460, and 470 formed along the circumference of the outer circumferential surface, so that a curvature is formed in a path connecting the upper end and the lower end along the outer surface.

2, when the insulation elastic block 40 is in direct contact with water or in a state in which moisture is likely to be attached due to high humidity, the corona can be easily advanced, and the inner space of the dielectric tube 30 (quartz tube) The electric charge charged on the outer surface of the quartz tube which is in contact with the water is reflected by the counter electrode 70 by the high frequency electric field to the surface corona, Causing a discharge / tracking phenomenon

Therefore, there is a risk that a high-frequency current which always generates plasma leaks out to the connection portion between the support head 10 and the dielectric tube 30, causing fire and burnout. The leakage current flows through the upper plate 62 of the water tank 60 to the counter electrode 70 while riding on the outer surface of the insulating elastic block 40.

Accordingly, the annular raised portions 450, 460, and 470 provided in the insulating elastic block 400 extend the creepage distance of the surface in order to suppress the leakage of the current flowing on the outer surface. That is, the current path is increased on the outer surface of the insulative elastic block 400 through which the current flows, thereby increasing the resistance to current flow. Further, the ridge portions 450, 460, and 470 have a curved surface of a gentle shape so that the electric field is not concentrated or the full speed line does not enter or exit.

The protrusions 450, 460 and 470 of the insulating elastic block 400 are arranged to cover an area between the upper end of the dielectric tube 30 and the lower end of the insertion protrusion 110. This is because the discharge electrode 20 is exposed in the region between the upper end of the dielectric tube 30 and the lower end of the insertion protrusion 11 and the risk of leakage of current is high. Therefore, even if the outer surface of the silicon contacts moisture, The silicon surface is made to have a sufficient thickness so that the insulation breakdown is prevented.

The insertion protrusion 110 of the support head 100 inserted into the insulative elastic block 400 is provided with an annular engagement recess 115 recessed along the circumference between its upper end and lower end.

The engaging groove 115 is provided to increase the engaging force of the inserting elastic block 400 with the engaging protrusion 410 of the inserting elastic block 400. The engaging groove 115 is formed on the inner circumferential surface of the inserting protrusion holding hole 410, (415).

One of the raised portions 450, 460 and 470 is located outside the engagement protrusion 415 so that the strength of the engagement protrusion 415 is complemented from the outer side so that the engagement groove 115 of the insertion protrusion 110 and the insertion It is possible to make the engagement protrusion 415 of the protruding head protrusion 410 to have a further increased coupling force.

7 and 8, the upper end of the insulating elastic block 400 of the present embodiment is inserted into the through hole 623 of the upper plate 62 of the water tub 60 to be inserted into the insertion protrusion The insulating elastic block 400 is fixed to the through hole 623 of the upper plate 62 by the pressing force that is applied to the insertion protruding end stopper 110 by the pressing force.

That is, the upper end of the insulating elastic block 400 is inserted into the through hole 623 of the upper plate 62 of the water tub 60 from below, and the insertion protrusion 110 is prevented from penetrating into the insertion protrusion The upper end portion of the insulating elastic block 400 is in a state of being pressed while being in close contact with the inner surface of the through hole 623,

An annular rim 440 protruding outward beyond the diameter of the through hole 623 is provided at the upper end of the insulating elastic block 40.

The annular rim 440 is engaged with the upper surface of the upper plate 62 in a state in which the insulative elastic block 400 is inserted into the through hole 623 of the upper plate 62 of the water tub 60 to support the insulative elastic block 400 can do. When the insulating elastic block 400 is caught by the annular rim 440 on the through hole 623 of the upper plate 62 of the water tank 60, The insulating elastic block 400 may be hooked on the upper surface and the lower surface of the upper plate 62 by being positioned so as to support the upper plate 450.

Since the insulative elastic block 400 can be fixed to the upper plate 62 without using a separate fixing member or adhesive, it is possible to greatly facilitate the repair and replacement of the apparatus, and the insertion projection 110 can be inserted into the insertion / It is possible to maintain the sealed state of the water tub 60 by the elastic force of the insulative elastic block 400 so that the structure can be formed without oozing out have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

10,100; Support head 11, 110; The insertion protrusions
11a; Free space 12; Air supply passage
13; A head main body 14; Air supply port
20; A discharge electrode 21; Center rod
22; A support 23; Ceramic insulation tubes
30; A dielectric tube 40, 400; Insulated elastic block
41,410; Insertion protruding director start 42; Construction of a dielectric plant
60; Water tank 62; Top plate
70; A counter electrode 81; Porous bubble generator
82; A power applying device 83; regulator
115; An engagement groove 415; Jaw
440; Annular frame 450, 460, 470; Ridge
623; Through-hole

Claims (8)

And an air supply passage (12) vertically formed at a central portion of the insertion protrusion (11) to be opened at a lower end of the insertion protrusion (11), the insertion protrusion );
A discharge electrode (20) vertically installed in the air supply passage (12) and extending to the lower side of the support head (10) to generate plasma;
A dielectric tube 30 into which a lower portion of the discharge electrode 20 is inserted, the tube being shaped like a vertically opened upper and lower ends; And
The insertion protruding portion of the insertion protruding portion 11 is inserted from the upper side and the dielectric protruding portion is inserted from the lower end of the dielectric tube 30 so as to communicate with the insertion protruding end stopper 41, And an insulation elastic block (40) provided with a valve opening (42)
The insertion protrusion 11 and the upper end of the dielectric tube 30 are respectively inserted into the insertion protruding end opening 41 and the dielectric energization opening 42 so as to have a predetermined gap from each other and are connected to each other in a noncontact state The plasma generating subassembly of the water treatment apparatus The method according to claim 1,
The support head 10 and the dielectric tube 30 are fitted to the insulation elastic block 40 such that the upper end of the dielectric tube 30 is positioned lower than the lower end of the insertion projection 11,
(12) and the dielectric tube (30) in an area between the upper end of the dielectric tube (30) and the lower end of the insertion projection (11) And a ceramic insulating tube (23) attached to the discharge electrode (20) in a state surrounding the discharge electrode The method according to claim 1,
Wherein the inserting projection and the insulative elastic block are formed in a vertically arranged columnar shape,
The outer peripheral surface of the insulating elastic block has a plurality of annular protruding portions (450, 460, and 470) formed along the periphery thereof so that the path connecting the upper end and the lower end along the outer surface is bent. Assembly The method of claim 3,
The support head and the dielectric tube are fitted to the insulative elastic block such that the upper end of the dielectric tube 30 is positioned lower than the lower end of the insertion protrusion,
Wherein the protrusions (450, 460, 470) are arranged to cover an area between an upper end of the dielectric tube and a lower end of the insertion protrusion. 5. The method of claim 4,
An annular engaging groove 115 is formed between the upper end and the lower end of the insertion protrusion along the circumference,
A locking protrusion (415) is formed on an inner circumferential surface of the protrusion protrusion for engaging the locking protrusion,
Wherein one of the ridges (450, 460, 470) is located on the outer side where the latching jaw is located. 6. The method according to any one of claims 1 to 5,
The discharge electrode (20) is held in close contact with the inner circumferential surface of the dielectric tube (30)
The dielectric tube 30 is made of quartz tube material,
The support head 10 is made of a ceramic material,
Characterized in that the insulating elastic block (40) is made of a silicone resin material. An upper plate 62 of the water tub 60 in which the through holes 623 are formed,
A support head 10 provided with a discharge electrode 20 having a vertical insertion protrusion 11 at its lower portion and extending downward from the insertion protrusion 11,
A dielectric tube 30 into which the discharge electrode 20 is inserted,
The insertion protruding portion of the insertion protruding portion 11 is inserted from the upper side and the dielectric protruding portion is inserted from the lower end of the dielectric tube 30 so as to communicate with the insertion protruding end stopper 41, And an insulation elastic block (40) provided with a valve opening (42)
The insertion protrusions 11 and the upper ends of the dielectric tubes 30 are formed at predetermined intervals so as not to contact each other in a state where the insertion protrusions 11 and the dielectric tube 30 are sandwiched between the first and second protrusions 41 and 42,
Wherein the inserting projection and the insulative elastic block are formed in a vertically disposed cylindrical shape,
The outer circumferential surface of the insulative elastic block has a plurality of annular protruding portions 450, 460 and 470 formed along the periphery thereof so that the path connecting the upper end and the lower end along the outer surface has a curved shape.
The upper end of the insulating elastic block
Wherein the insertion protrusion is fitted into the through hole (623) of the upper plate (62) so as to be in tight contact with the through hole (623) The plasma generating subassembly 8. The method of claim 7,
The insulating elastic block is provided at its upper end with an annular rim protruding outwardly beyond the diameter of the through hole (623)
Wherein the annular rim and the ridges (450, 460, 470) are hooked on upper and lower surfaces of the upper plate (62) to support the insulative elastic block

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