KR101921254B1 - Air Circulation Nozzle Device for Fluidized Bed Combustor - Google Patents

Abstract

The present invention relates to an air circulation nozzle device for a fluidized bed boiler. According to the present invention, an air injection nozzle supplying air to a fluidized bed combustion furnace of a fluidized bed boiler is protected by a nozzle protection member, and thus deformation attributable to a high temperature generated in the fluidized bed combustion furnace can be prevented. The present invention includes an air supply pipe (100) supplying air in a state of communicating with a fluidized bed combustion furnace (10) of a fluidized bed boiler, an air injection nozzle (200) provided in the air supply pipe (100) and injecting the supplied air to the fluidized bed combustion furnace (10), and a nozzle protection member (300) installed in the air injection nozzle (200) and protecting the air injection nozzle (200) from a collision with a solid fuel burned in the fluidized bed combustion furnace (10) or a flow medium for heat transfer. The air injection nozzle (200) is provided with an air flow path (210) so that one end of the air supply pipe (100) is inserted and the air supplied from the air supply pipe (100) is perfused. An outward through hole (220) is formed in the air flow path (210) so that the air perfused in the air flow path (210) is injected to the outside.

Description

TECHNICAL FIELD [0001] The present invention relates to an air circulation nozzle device for a fluidized bed boiler,

The present invention relates to an air circulation nozzle device for a fluidized bed boiler, which can prevent an air injection nozzle for supplying air to a fluidized bed combustion furnace of a fluidized bed boiler from being deformed by a high temperature generated in a fluidized bed combustion furnace, .

Fluidized bed technology has recently emerged as a strong competitor to conventional pulverized coal combustion boilers. Fluidized bed boilers have been used to control the flow of particles (coal, limestone, and so on) heated by fuel combustion in a furnace (Low carbon, biomass, waste energy, etc.) due to its excellent fuel adaptability and can be utilized optimally for the consumption of low grade coal including anthracite. It is emerging as the optimal solution of the utilization technology.

In addition, due to the utilization of renewable energy such as low-cost imported coal and refuse derived fuel, the annual energy production cost can be reduced to about 60%, attracting attention as an optimal utilization technique for lowering the cost of electric energy, .

It has a high heat transfer, a heat capacity, a uniform temperature distribution, a high efficiency, a desulfurization method using limestone (CaCO 3), and a low operating temperature of 800 ° C. or lower, (NOx) generation is unnecessary and separate desulfurization and denitrification facilities are not required. In order to maintain the emission standard of environmental pollutants, consideration is given to the desulfurization equipment and selective catalytic reduction required for pulverized coal combustion. The total construction cost for the construction of the boiler is inexpensive.

Here, the structure of the fluidized bed boiler will be schematically described. A fluidized bed combustion furnace in which a fluidized bed (sand) is filled to form a fluidized bed, and a fluidized medium heated by the combustion of the fuel conveys heat to produce steam energy, (cyclone) for separating and collecting the fly ash together with the combustion gas generated in the fluidized bed combustion furnace is connected to the fluidized bed combustion furnace, and the fuel collected by the ash separator A particle loop unit for returning the particles to the fluidized bed combustion furnace is connected to the fluidized bed combustion furnace in the rotary separator and a plurality of nozzles for dispersed injection of air supplied from the outside are installed upright on the lower side of the fluidized bed combustion furnace.

This efficient flow of the fluidized bed and the performance of the fuel combustion can be improved by the air injected from the nozzles.

However, as the waste solid fuel is burnt, a temperature of 800 to 900 degrees centigrade is generated in the fluidized bed combustion furnace. The internal temperature of the fluidized bed combustion furnace is high at a temperature higher than 500 to 800 degrees Celsius, which is a temperature range of a creep strength of a nozzle made of a metal material, so that the nozzle is deformed or damaged. That is, the efficiency of the boiler may be lowered.

The background art of the present invention is disclosed in Published Patent Application No. 10-2011-0079040 (July 07, 2011) filed in the Korean Intellectual Property Office.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fluidized bed combustion apparatus capable of preventing an air injection nozzle for supplying air to a fluidized bed combustion furnace of a fluidized bed boiler from being deformed by a high temperature generated in a fluidized bed combustion furnace, Thereby providing a circulating nozzle device.

An air circulation nozzle apparatus for a fluidized bed boiler according to an embodiment of the present invention includes an air supply pipe 100 for supplying air in a state of being connected to a fluidized bed combustion furnace 10 of a fluidized bed boiler, An air injection nozzle 200 for injecting air to be supplied to the fluidized bed combustion furnace 10 and a collision of the fluid medium for solid fuel or heat transfer in the fluidized bed combustion furnace 10 in a state of being installed in the air injection nozzle 200 A mounting member 400 formed of a bolt for mounting the nozzle protecting member 300 to the air jetting nozzle 200 and a nozzle protecting member 300 for protecting the air jetting nozzle 200 from the air jetting nozzle 200. [ 200 and a nozzle protecting member 300 to provide a shock absorbing member 500 having a superior refractory performance and a buffer function for mitigating an external impact. The air injection nozzle 200 is provided with an air supply pipe 100, Is supplied from the air supply pipe (100) while one end of the air supply pipe A spray hole 220 is formed through the air passage 210 so as to discharge the air to be discharged from the air passage 210 to the outside, The outer mounting hole 230 is formed of a screw tap and the nozzle protecting member 300 is connected to the air injection nozzle 300. [ The air injection nozzle 200 is formed of a ceramic material so as to protect the air injection nozzle 200 from the high temperature generated in the fluidized bed combustion furnace 10, The space 310 is formed and the exposure hole 320 is communicated with the insertion space 310 so that the external mount 230 of the air injection nozzle 200 inserted into the insertion space 310 is exposed to the outside And the bolt as the mounting member 400 is screwed into the external mounting hole 230 through the exposure hole 320 And the cushioning member 500 has a disk-like ceramic sheet which is in surface contact with the air injection nozzle 200 and the nozzle protection member 300 while passing through the center portion thereof, and the outer peripheral surface of the air injection nozzle 200, And a tubular ceramic tube which is in surface contact with the inner circumferential surface of the protective member 300.
The air circulation nozzle device for a fluidized bed boiler according to another embodiment of the present invention includes an air supply pipe 100 for supplying air in a state of being connected to a fluidized bed combustion furnace 10 of a fluidized bed boiler, An air injection nozzle 200 for injecting air supplied and installed into the fluidized bed combustion furnace 10 and a flow medium for solid fuel or heat transfer which is burned in the fluidized bed combustion furnace 10 in a state of being installed in the air injection nozzle 200, And the nozzle protection member 300 protects the air injection nozzle 200 from the collision of the air supply nozzle 100 and the air supply nozzle 200. The air supply nozzle 100 is inserted into one end of the air supply nozzle 100, And an injection hole 220 is formed in the lower part of the air injection nozzle 200. The air injection hole 200 is formed in the air passage 210 so that the air passing through the air passage 210 is discharged to the outside, , And the air supply pipe (100) And one end thereof is spaced apart from the inner circumferential surface of the air flow path 210 while being inserted into the air flow path 210 of the air injection nozzle 200, The air injection nozzle 200 located in the fluidized bed combustion furnace 10 is heated when air is not injected because the injection hole 220 of the air injection nozzle 200 is blocked and the air is not injected And the temperature of the air supply pipe 100 for supplying air is lower than that of the air injection nozzle 200 so that the air supplied to the air flow path 210 through one end of the air supply pipe 100 Convective phenomenon is performed in which the air passes through the convection hole 101 and then moves to the air supply pipe 100 again.
According to another embodiment of the present invention, there is provided an air circulation nozzle apparatus for a fluidized bed boiler, comprising: an air supply pipe 100 for supplying air in a state of being connected to a fluidized bed combustion furnace 10 of a fluidized bed boiler; An air injection nozzle 200 for injecting air supplied to the fluidized bed combustion furnace 10 and supplying the air to the fluidized bed combustion furnace 10; And a nozzle protecting member 300 that protects the air injection nozzle 200 from a collision of the medium and the air supply pipe 100 is installed with one end inserted into the air flow path 210 of the air injection nozzle 200, And a discharge hole 111 through which the air supplied to the air injection nozzle 200 flows and which is inserted into the outer tube 110. The outer tube 110 is inserted into the outer tube 110, It is installed at one end to shut off the air supplied from outside, The air injection nozzle 200 includes an air flow passage 210 through which air supplied from the air supply pipe 100 is inserted while one end of the air supply pipe 100 is inserted into the air injection nozzle 200, And an injection hole 220 is formed in the air passage 210 so as to be laterally passed through the air passage 210 so that the air passing through the air passage 210 is discharged to the outside.

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Preferably, the discharge hole 111 is formed to be smaller than the spray hole 220 of the air spray nozzle 200.

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Preferably, the bolt as the mounting member 400 has a diameter equal to or greater than the diameter of the nozzle protecting member 300.

The present invention is advantageous in that the air injection nozzle for supplying air to the fluidized bed combustion furnace of the fluidized bed boiler is protected by the nozzle protecting member and can be prevented from being deformed by the high temperature generated in the fluidized bed combustion furnace.

In addition, when the air injection nozzle is clogged and air can not be sprayed, the air is convected through the convection hole formed to communicate with the air supply pipe for supplying air laterally, so that the overheating of the air injection nozzle can be prevented.

In addition, in the case where the air supply pipe is composed of the inner pipe and the outer pipe and the air injection nozzle is clogged so that the air can not be injected, the air supplied through the inner pipe is discharged to the outside through the outer pipe. Can be prevented.

In addition, since the nozzle protecting member is made of a ceramic material and formed into a cap shape to insert the air injection nozzle, the air injection nozzle can be protected from the high temperature generated in the fluidized bed combustion furnace.

Further, since the mounting member for mounting the nozzle protecting member to the air jetting nozzle is constituted by a bolt, the head covers the nozzle protecting member, so that it is possible to prevent the nozzle protecting member from being damaged from collision of the falling solid fuel.

1 is a view showing a state where the present invention is applied to a fluidized bed combustion furnace of a fluidized bed boiler.
2 is a perspective view showing an air circulation nozzle according to an embodiment of the present invention;
3 is an exploded perspective view showing the decomposed state of the present invention.
4 (a) and 4 (b) are cross-sectional views showing a state of use of an air supply pipe according to an embodiment of the present invention.
5 (a) and 5 (b) are cross-sectional views showing a state of use of an air supply pipe according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 to 5, an air circulation nozzle device for a fluidized bed boiler according to an embodiment of the present invention includes an air supply pipe 100 for supplying air in a state of being connected to a fluidized bed combustion furnace 10 of a fluidized bed boiler, An air injection nozzle 200 for injecting air supplied to the air supply pipe 100 into the fluidized bed combustion furnace 10 and a fluidized bed combustion furnace 10 installed to cover the air injection nozzle 200, And a mounting member 400 for mounting the nozzle protecting member 300 to the air jet nozzle 200. The nozzle protecting member 300 may be formed of a material having a high thermal conductivity.

First, an air injection nozzle 200 is installed in a lower portion of a fluidized bed combustion furnace 10 in a fluidized bed boiler, and an air injection device 20 is connected to an air injection nozzle 200. At this time, in order to heat the fluidized medium, when the solid fuel is burned in the fluidized bed combustion furnace 10, the air is injected into the fluidized bed combustion furnace 10 through the air injection nozzle 200 by the operation of the air injection device 20, .

Here, the solid fuel may include industrial waste or household waste.

The air supply pipe 100 is a tubular body having a convection hole 101 through which air flows laterally from one end of the air injection nozzle 200 of the air injection nozzle 200, . Accordingly, when air is supplied through the air supply pipe 100, the air is injected into the fluidized bed combustion furnace 10 through the air injection nozzle 200.

However, when the injection hole 220 is blocked by the solid fuel or the fluid medium that is burned in the fluidized bed combustion furnace 10 and air can not be injected as shown in FIG. 4 (b), the air The injection nozzle 200 is heated by a temperature of 800 degrees centigrade and the temperature of the air is generated because the temperature of the air supply pipe 100 supplying air is lower than the temperature of the air injection nozzle 200 being heated. As a result, the air supplied from the air supply pipe 100 to the air injection nozzle 200 passes through the convection hole 101 and then conveys the air to the air supply pipe 100 again. Therefore, the air heated in the air injection nozzle 200 and the unheated air in the air supply pipe 100 can be circulated to each other by convection, thereby preventing the air injection nozzle 200 from being overheated, 200 can be prevented from being deformed at a high temperature of 800 degrees centigrade. That is, since the air injection nozzle 200 is prevented from being deformed, the efficiency of the fluidized bed combustion furnace 10 can be prevented from being lowered.

5, one end of the air supply pipe 100 is inserted into the air flow path 210 of the air injection nozzle 200 to be described later. The air supply pipe 100 is laterally passed through the air injection nozzle 200 An outer tube 110 formed with a discharge hole 111 through which the supplied air flows, and an outer tube 110 having one end closed at one end of the outer tube 110 in a state of being inserted into the outer tube 110, To the air injection nozzle (200).

The outer tube 110 is inserted into the air passage 210 of the air injection nozzle 200 while being inserted into the fluidized bed combustion furnace 10 and the discharge hole 111 is located in the air passage 210. Here, the discharge hole 111 is formed to be smaller than the discharge hole 220 of the air injection nozzle 200.

The other end of the outer tube 110 opposite to the one end of the discharge hole 111 is opened. That is, when air flows through the discharge hole 111, the air can be discharged to the outside through the other end of the outer tube 110.

The inner tube 120 has a smaller diameter than the outer tube 110 and is inserted into the outer tube 110 and is formed in a flange shape so that one end thereof is connected to the outer tube 110 by bolting or welding.

Accordingly, when the air injected into the inner tube 120 is supplied to the air injection nozzle 200, the air is injected into the fluidized bed combustion furnace 10 through the injection hole 220 of the air injection nozzle 200. At this time, since the injection hole 220 is larger than the discharge hole 111, most of the air can be injected through the injection hole 220. As the air is continuously injected through the injection hole 220, the air is continuously supplied to the air injection nozzle 200, so that the heating of the air injection nozzle 200 can be minimized due to the high temperature.

However, if the injection hole 220 of the air injection nozzle 200 is blocked and the air supplied through the internal tube 120 can not be injected through the air injection nozzle 200, And is discharged to the outside through the outer pipe 110. That is, when the injection hole 220 is closed, air can be discharged to the outside through the discharge hole 111.

If the air injection nozzle 200 is blocked and air can not be supplied through the internal pipe 120, the air injection nozzle 200 may be deformed by a high temperature of 800 degrees centigrade. However, when the air injection nozzle 200 is clogged, the air flowing into the discharge hole 111 is discharged to the outside through the external pipe 110, so that external air can be continuously supplied to one end of the internal pipe 120, The injection nozzle 200 can be prevented from being deformed by the high temperature. That is, since the deformation of the air injection nozzle 200 is prevented, long-term use of the air injection nozzle 200 can be assured. As a matter of course, since the deformation of the air injection nozzle 200 is prevented, the efficiency reduction of the fluidized bed combustion furnace 10 can be prevented.

The air injection nozzle 200 is formed with an air flow passage 210 through which air supplied from the air supply pipe 100 is inserted while one end of the air supply pipe 100 is inserted, An injection hole 220 is formed so as to pass through the air passage 210 to the outside.

The convection hole 101 and the discharge hole 111 of the air supply pipe 100 described above are positioned in the air flow path 210.

Accordingly, the air supplied from the air supply pipe 100 flows through the air passage 210 and is injected into the fluidized bed combustion furnace 10 through the injection hole 220. At this time, when the injection hole 220 is closed, the air passing through the air passage 210 flows through the convection hole 101 and the discharge hole 111 of the outer tube 110.

Here, the injection hole 220 may be formed so as to be inclined sideways from the air injection nozzle 200. Further, the plurality of injection holes 220 may be formed in various directions, so that air can be injected in various directions.

Outer side of the air injection nozzle 200 is formed an external mounting hole 230 to which the mounting member 400 is coupled to mount the nozzle protecting member 300. The external mount 230 may be a screw tap or a screw shaft.

The nozzle protecting member 300 is made of a ceramic material so as to protect the air injection nozzle 200 from a high temperature generated in the fluidized bed combustion furnace 10 while being formed in a cap shape to be coupled to cover the air injection nozzle 200 . Since the nozzle protecting member 300 made of a ceramic material is not deformed at a high temperature, it can cover and protect the air injection nozzle 200, so that deformation of the air injection nozzle 200 made of metal can be prevented .

The nozzle protecting member 300 is formed with an insertion space 310 into which the air injection nozzle 200 is inserted and an outer mounting hole 230 of the air injection nozzle 200 inserted into the insertion space 310 is connected to the outside And the exposure hole 320 is formed in the insertion space 310 so as to be exposed.

The nozzle protecting member 300 may be mounted on the air injection nozzle 200 by a mounting member 400 mounted on the outer mounting hole 230 of the air injection nozzle 200.

The mounting member 400 may be constituted by a bolt threaded into the threaded tab, which is the external mounting hole 230, or may be composed of a nut screwed to the threaded shaft of the external mounting hole 230. When the bolt or nut as the mounting member 400 is coupled to the external mounting hole 230 exposed through the exposure hole 320 in a state of pressing the nozzle protecting member 300, The state in which the nozzle 200 is mounted is firmly maintained.

Here, the bolt as the mounting member 400 may be formed with a head which is equal to the diameter of the nozzle protecting member 300 or is larger than the diameter of the nozzle protecting member 300. Therefore, the head of the bolt, which is the mounting member 400, covers the nozzle protecting member 300 to prevent the nozzle protecting member 300 from being broken from the solid fuel falling down. The head may be formed in a hemispherical shape so that the solid fuel or the fluid medium falling in the fluidized bed combustion furnace 10 is moved away. As a result, even if the solid fuel to be dropped falls against the head, it can be mitigated while the impact is reduced.

Meanwhile, a buffer member 500 may be provided between the air injection nozzle 200 and the nozzle protection member 300 to serve as a buffer. The cushioning member 500 has a circular plate-like ceramic sheet which is in surface contact with the air spraying nozzle 200 and the nozzle protecting member 300 while passing through the center portion thereof and the outer peripheral surface of the air spraying nozzle 200 and the outer surface of the nozzle protecting member 300 And includes a tubular ceramic tube which is in surface contact with the inner peripheral surface.

A disk-shaped ceramic sheet, which is a cushioning member 500, may also be provided between the bolt as the mounting member 400 and the nozzle protecting member 300.

Since the cushioning member 500 is made of ceramics, the air-spraying nozzle 200 of the metal material and the nozzle protecting member 300 of the ceramic material are in contact with each other while being resistant to the high temperature of the fluidized bed combustion furnace 10, And the external impact can be relieved.

As described above, the present invention can reduce the impact caused by the collision of the solid fuel dropped while preventing the nozzle for supplying air to the fluidized bed combustion furnace of the fluidized bed boiler from being deformed due to the high temperature generated in the fluidized bed combustion furnace, This is a very useful invention that can be widely applied to an air circulation nozzle device.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, and the meaning and scope of the claims and their equivalents It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

10: Fluidized bed combustion furnace 20: Air injection device
100: air supply pipe 101: convection hole
110: outer tube 111: discharge hole
120: inner tube 200: air injection nozzle
210: air passage 220: injection hole
230: external mounting part 300: nozzle protecting member
310: insertion space 320: exposure hole
400: mounting member

Claims (8)

An air supply pipe 100 for supplying air in a state of being connected to the fluidized bed combustion furnace 10 of the fluidized bed boiler,
An air injection nozzle 200 installed in the air supply pipe 100 and injecting air supplied to the fluidized bed combustion furnace 10,
A nozzle protecting member 300 for protecting the air injection nozzle 200 from a collision of a solid fuel burned in the fluidized bed combustion furnace 10 or a fluid medium for heat transfer in a state where the air injection nozzle 200 is installed,
A mounting member 400 composed of a bolt for mounting the nozzle protecting member 300 to the air jetting nozzle 200,
And a cushioning member (500) provided between the air injection nozzle (200) and the nozzle protecting member (300) and having a superior refractory performance and buffering the external impact,
In the air injection nozzle 200,
An air passage 210 through which the air supplied from the air supply pipe 100 flows is formed while one end of the air supply pipe 100 is inserted,
An injection hole 220 is formed through the air passage 210 so that the air passing through the air passage 210 is discharged to the outside,
An outer mounting hole 230 to which the mounting member 400 is coupled to mount the nozzle protecting member 300 is formed on the outer side,
The external mounting hole 230 is formed of a screw tab,
The nozzle protecting member 300 is formed in a cap shape to be coupled to cover the air injection nozzle 200 and is made of a ceramic material so as to protect the air injection nozzle 200 from the high temperature generated in the fluidized bed combustion furnace 10 ,
An insertion space 310 into which the air injection nozzle 200 is inserted is formed,
The exposure hole 320 is formed in the insert space 310 so that the external mount 230 of the air injection nozzle 200 inserted into the insert space 310 is exposed to the outside,
The bolt as the mounting member 400 is coupled to the screw tab as the external mounting hole 230 through the exposure hole 320,
The buffer member 500
A ceramic sheet in the form of a disk which is in surface contact with the air spraying nozzle 200 and the nozzle protecting member 300 while passing through the center portion,
And an outer peripheral surface of the air injection nozzle (200) and an inner peripheral surface of the nozzle protecting member (300). 2. The air circulating ceramic nozzle apparatus for a fluidized bed boiler according to claim 1,
An air supply pipe 100 for supplying air in a state of being connected to the fluidized bed combustion furnace 10 of the fluidized bed boiler,
An air injection nozzle 200 installed in the air supply pipe 100 and injecting air supplied to the fluidized bed combustion furnace 10,
And a nozzle protecting member (300) for protecting the air injection nozzle (200) from a collision of a solid fuel burned in the fluidized bed combustion furnace (10) or a fluidizing medium for heat transfer while being installed in the air injection nozzle (200)
In the air injection nozzle 200,
An air passage 210 through which the air supplied from the air supply pipe 100 flows is formed while one end of the air supply pipe 100 is inserted,
A spray hole 220 is formed at a lower portion of the air spray nozzle 200 so as to be sideways in the air passage 210 so that air to be perfused in the air passage 210 is sprayed to the outside,
A convection hole 101 through which the air supply pipe 100 is passed through from one end to the other and through which the air flows is installed and inserted into the air passage 210 of the air injection nozzle 200, When the convection halls 101 are positioned in the air flow passage 210 and the injection holes 220 of the air injection nozzles 200 are blocked so that no air is injected into the fluidized bed combustion furnace 10, Since the temperature of the air injection nozzle 200 is lower than the temperature of the air injection nozzle 200 for supplying the air, a temperature difference of the air is generated and the air is supplied to the air supply pipe 100 through one end of the air supply pipe 100 Wherein a convection phenomenon occurs in which the air supplied to the flow path (210) passes through the convection hole (101) and then moves to the air supply pipe (100).
An air supply pipe 100 for supplying air in a state of being connected to the fluidized bed combustion furnace 10 of the fluidized bed boiler,
An air injection nozzle 200 installed in the air supply pipe 100 and injecting air supplied to the fluidized bed combustion furnace 10,
And a nozzle protecting member (300) for protecting the air injection nozzle (200) from a collision of a solid fuel burned in the fluidized bed combustion furnace (10) or a fluidizing medium for heat transfer while being installed in the air injection nozzle (200)
The air supply pipe 100
An outer tube 110 having one end inserted into the air passage 210 of the air injection nozzle 200 and formed with a discharge hole 111 through which the air supplied to the air injection nozzle 200 flows, )and,
And an inner tube 120 installed at one end of the outer tube 110 in a state of being inserted in the outer tube 110 and supplying air supplied from the outside to the air injection nozzle 200,
In the air injection nozzle 200,
An air passage 210 through which the air supplied from the air supply pipe 100 flows is formed while one end of the air supply pipe 100 is inserted,
Wherein an injection hole (220) is formed through the air passage (210) so that the air passing through the air passage (210) is ejected to the outside.
The method of claim 3,
Wherein the discharge hole (111) is formed to be smaller in size than the injection hole (220) of the air injection nozzle (200).
delete delete delete The method according to claim 1,
Characterized in that the bolt as the mounting member (400) is formed with a head which is equal to or larger than the diameter of the nozzle protecting member (300) or larger than the diameter of the nozzle protecting member (300).

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