KR102665211B1 - Nozzle binding apparatus - Google Patents

Abstract

The present invention aims to provide a nozzle binding device that can replace an air injection nozzle that is deformed by the high temperature generated in the fluidized bed combustion furnace in the process of supplying air to the fluidized bed combustion furnace of the fluidized bed boiler.
A feature of the present invention is that the air injection nozzle 100, which sprays air into the lower part of the fluidized bed combustion furnace 10 in the fluidized bed boiler, is detachably connected to the air injection nozzle 100 and supplies air to the air injection nozzle 100. A nozzle binding unit that binds the air supply pipe 200 and the air injection nozzle 100 provided in the air supply pipe 200 to maintain the air injection nozzle 100 inserted into the air supply pipe 200. Includes 300.

Description

Nozzle binding apparatus

The present invention relates to a nozzle binding device that can replace an air injection nozzle that is deformed by the high temperature generated in the fluidized bed combustion furnace in the process of supplying air to the fluidized bed combustion furnace of a fluidized bed boiler.

Recently, fluidized bed technology has emerged as a strong competitor to traditional pulverized coal-fired boilers. Fluidized bed boilers allow the flow of particles (coal, limestone, ash, etc.) heated by fuel combustion within the combustion furnace. As a power generation method that produces steam, it has the advantage of being able to utilize a variety of low-grade fuels (low-grade coal, biomass, waste energy, etc.) with excellent fuel adaptability, and can be optimally used for the consumption of low-grade coal, including anthracite, for domestic energy production and It is emerging as the optimal solution for use technology.

In addition, due to the use of renewable energy such as cheap imported low-grade coal and waste derived fuel, annual energy production costs can be reduced by about 60%, so it is attracting attention as the optimal technology for lowering the cost of electric energy, which is the basis of the national economy. I'm receiving it.

In addition, it has high heat transfer, heat capacity, uniform temperature distribution, high efficiency, and desulfurization during combustion using limestone (CaCO3). Due to the low operating temperature of less than 800 degrees Celsius, nitrogen oxides are eliminated. (NOx) generation is low, so there is no need for separate desulfurization and denitrification equipment. In order to maintain the emission standards for environmental pollutants, the construction costs of wet desulfurization equipment and selective catalytic reduction required when burning pulverized coal are considered. Since there is no need to do this, the total construction cost for boiler construction is low.

Here, to roughly explain the structure of the fluidized bed boiler, a fluidized bed is formed by filling the inside with a fluidized medium (sand), and the fluidized medium heated by combustion of fuel transfers heat to produce steam energy. (fluidized-bed combustor) is equipped, and an ash separator (cyclone) that separates and collects ash flying together with combustion gases generated from the fluidized bed combustion furnace is connected to the fluidized bed combustion furnace, and the fuel collected by the ash separation device A particle circulation device (loopseal) that returns particles to the fluidized bed combustion furnace is connected to the fluidized bed combustion furnace from the ash separation device, and a number of nozzles are mounted standing on the lower side of the fluidized bed combustion furnace for dispersed injection of air supplied from the outside.

Efficient fluidization of the fluidized bed and fuel combustion performance can be improved by the air sprayed from the nozzles.

And, as the waste solid fuel is burned, a temperature of 800 to 900 degrees Celsius is generated in the fluidized bed combustion furnace. Since the temperature inside the fluidized bed combustion furnace is higher than 500 to 800 degrees Celsius, which is the temperature range of the creep strength of the nozzle made of metal, the nozzle is deformed or damaged.

However, since the nozzles are integrated, there is a problem in that damaged nozzles cannot be replaced, and the efficiency of the boiler may be reduced.

Public Patent Publication No. 10-2011-0079040 (2011.07.07.)

The present invention aims to provide a nozzle binding device that can replace an air injection nozzle that is deformed by the high temperature generated in the fluidized bed combustion furnace in the process of supplying air to the fluidized bed combustion furnace of the fluidized bed boiler.

The nozzle binding device according to the present invention is an air injection nozzle 100 that sprays air to the lower part of the fluidized bed combustion furnace 10 in a fluidized bed boiler, and the air injection nozzle 100 is detachably connected to the air injection nozzle 100. ), the air supply pipe 200 that supplies air to the It includes a nozzle coupling portion 300, wherein the nozzle coupling portion 300 includes a binding casing 310 in which the air supply pipe 200 is penetrated and fixed, and an air supply pipe ( A tube pressurizing part 320 that pressurizes the air supply pipe 200 so that 200 pressurizes and fixes the air injection nozzle 100, and a tube pressurizing part (320) so that the tube pressurizing part 320 presses the air supply pipe 200. It is characterized by including a pressure control unit 330 that operates 320).

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Preferably, the binding casing 310 includes a lower plate 311 that is fixed to the lower part of the air supply pipe 200, and an upper plate that is spaced upward from the lower plate 311 and is fixed to the upper part of the air supply pipe 200. (312), the lower end is fixed to the outside of the lower plate 311, the upper end is fixed to the outside of the upper plate 312, and the middle pipe body 313 has an internal space in which the pipe pressure portion 320 is accommodated. It is characterized by

Preferably, in another nozzle binding device according to the present invention, an air injection nozzle 100 that sprays air to the lower part of the fluidized bed combustion furnace 10 in a fluidized bed boiler and the air injection nozzle 100 are detachably connected and the air injection nozzle 100 is detachably connected to the air injection nozzle 100. The air supply pipe 200 that supplies air to the injection nozzle 100 and the air injection nozzle 100 in the state provided in the air supply pipe 200 are connected to insert the air injection nozzle 100 into the air supply pipe 200. It includes a nozzle fastening part 300 that maintains the connected state, and the nozzle fastening part 300 is fixed to the upper part of the air supply pipe 200 in a connected state and is built into the binding casing 310. A tube pressurizing part 320 pressurizes the air injection nozzle 100 that penetrates the binding casing 310 and is inserted into the air supply pipe 200 in the state, and the tube pressurizing part 320 presses the air jet nozzle 100. It is characterized by including a pressurizing operation unit 330 that operates the tube pressurizing unit 320 to pressurize.

Preferably, the binding casing 310 includes a lower plate 311 fixed to the upper part of the air supply pipe 200, an upper plate 312 spaced upward from the lower plate 311, and a lower end outside the lower plate 311. It is characterized by comprising a middle pipe body 313 that is fixed and has an upper end fixed to the outside of the upper plate 312 and has an internal space in which the pipe pressing portion 320 is accommodated.

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Preferably, the pipe pressurizing unit 320 is an external pressurizing pipe body 321 that is embedded in the binding casing 310 and moves in the direction from the air injection nozzle 100 to the air supply pipe 200 by operation of the pressurizing operation unit 330. And, it is located inside the external pressurizing pipe body 321 and is provided to surround the air supply pipe 200, and the diameter is narrowed by the pressure caused by the movement of the external pressurizing pipe body 321, thereby pressurizing the air injection nozzle 100. It is characterized in that it includes an internal pressurizing pipe body 322.

Preferably, the external pressurizing pipe body 321 is formed with a vertical length shorter than the length of the internal pressurizing pipe body 322, and the external pressurizing pipe body 321 has an inner inclined surface 325 on the inner circumferential surface whose inner diameter narrows from the bottom to the top. ) is formed, and the internal pressurizing pipe body 322 is characterized by an outer inclined surface 324 formed on the outer peripheral surface whose outer diameter widens from the top to the bottom.
Preferably, the subplate 312 is formed with a plurality of screw tabs 314 distributed, and the upper end of the external pressurizing pipe body 321 is located directly below the screw tab 314 formed on the upper plate 312, The operating unit 330 is characterized by being composed of a bolt that is screwed to the screw tab 314 of the upper plate 312 and pressurizes the tube pressurizing unit 320.

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The present invention has the effect of replacing an air injection nozzle that is deformed by the high temperature generated in the fluidized bed combustion furnace in the process of supplying air to the fluidized bed combustion furnace of the fluidized bed boiler.

Figure 1 is a diagram schematically showing the state in which an air injection nozzle is applied to the fluidized bed combustion furnace of a general fluidized bed boiler.
Figure 2 is a perspective view showing the present invention.
Figure 3 is an exploded perspective view showing the air injection nozzle of the present invention separated from the nozzle coupling portion installed in the air supply pipe.
Figure 4 is an exploded perspective view showing the disassembled state of the nozzle coupling portion applied to the present invention.
Figure 5 is a partial cross-sectional view showing the air injection nozzle of the present invention separated from the nozzle coupling portion.
Figure 6 is a partial cross-sectional view showing the air injection nozzle of the present invention inserted into the air supply pipe through the nozzle coupling portion.
Figure 7 is a partial cross-sectional view showing the air injection nozzle inserted into the air supply pipe of the present invention fixed by the nozzle fastener.
Figure 8 is a partial cross-sectional view showing another embodiment of the nozzle coupling part of the present invention.
Figure 9 is a partial cross-sectional view showing the air injection nozzle inserted into the air supply pipe through the nozzle coupling part of the present invention.
Figure 10 is a partial cross-sectional view showing a state in which the nozzle coupling part of the present invention pressurizes and fixes the air injection nozzle inserted into the air supply pipe.

Hereinafter, a nozzle binding device according to embodiments of the present invention will be described in detail with reference to the attached drawings. Since the present invention can be subject to various changes and can have various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention. While describing each drawing, similar reference numerals are used for similar components. In the attached drawings, the dimensions of the structures are enlarged from the actual size for clarity of the present invention, or reduced from the actual size to understand the schematic configuration.

First, as shown in FIG. 1, an air injection nozzle 100 is installed at the lower part of the fluidized bed combustion furnace 10 in a fluidized bed boiler, and an air injection device 20 is connected to the air injection nozzle 100. At this time, in order to heat the fluidized medium, while solid fuel is being burned in the fluidized bed combustion furnace 10, external air is blown into the fluidized bed combustion furnace 10 through the air injection nozzle 100 by the operation of the air injection device 20. is supplied to

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

As shown in FIGS. 2 to 7, the nozzle binding device according to the present invention includes an air injection nozzle 100 that sprays air to the lower part of the fluidized bed combustion furnace 10 in a fluidized bed boiler, and an air injection nozzle 100. The air injection nozzle 100 is connected to the air supply pipe 200, which is detachably connected and supplies air to the air injection nozzle 100, and the air injection nozzle 100 in the state provided in the air supply pipe 200. It includes a nozzle coupling portion 300 that maintains the inserted state in the air supply pipe 200.

The air injection nozzle 100 is connected to the air supply pipe 200 and includes a nozzle pipe body 110 through which air flows so as to spray external air supplied through the air supply pipe 200 into the fluidized bed combustion furnace 10. It includes a nozzle head 120 that is connected to 110 and has nozzle holes 121 through which air is discharged.

The air supply pipe 200 is installed at the lower part of the fluidized bed combustion furnace 10 in the fluidized bed boiler and consists of a pipe body through which the air supplied from the air injection device 20 flows through and supplies it to the air injection nozzle 100.

Therefore, when air is supplied to the air supply pipe 200 through the air injection device 20, it is injected into the fluidized bed combustion furnace 10 through the air injection nozzle 100, so that solid fuel is burned in the fluidized bed combustion furnace 10. In this state, the fluid medium is heated.

In addition, the lower part of the air injection nozzle 100 is formed with a diameter smaller than the diameter of the air supply pipe 200, and is inserted into and fixed in the air supply pipe 200. That is, the lower end of the air injection nozzle 100 is inserted into and fixed to the upper end of the air supply pipe 200. At this time, a seal is installed at the bottom of the air injection nozzle 100 to prevent air loss.

The nozzle binding unit 300 includes a binding casing 310 through which the air supply pipe 200 is penetrated and fixed, and the air supply pipe 200 pressurizes the air injection nozzle 100 while embedded in the binding casing 310. A tube pressurizing unit 320 that pressurizes the air supply pipe 200 to fix it, and a pressurizing operation unit 330 that operates the tube pressurizing unit 320 so that the tube pressurizing unit 320 pressurizes the air supply pipe 200. Includes.

The binding casing 310 not only maintains the built-in state of the pipe pressing portion 320 but also protects it from being exposed to the outside.

This binding casing 310 includes a lower plate 311 that is fixed to the lower part of the air supply pipe 200, and an upper plate that is spaced upward from the lower plate 311 and is fixed to the upper part of the air supply pipe 200 ( 312), and a middle pipe body 313 having a lower end fixed to the outside of the lower plate 311 and an upper end fixed to the outside of the upper plate 312, and an internal space in which the pipe pressing portion 320 is accommodated.

The lower plate 311 and the upper plate 312 are formed in the shape of a disk, and a hole through which the air supply pipe 200 passes is formed in the middle, so that the outer peripheral surface of the air supply pipe 200 is in close contact with the inner peripheral surface of the hole and is bolted to the air supply pipe 200. It can be fixed by welding.

The middle pipe 313 is formed in a cylindrical shape with an internal space penetrating up and down and can be fixed to the lower plate 311 and the upper plate 312 by bolts or welding. That is, the outer peripheral surface of the air supply pipe 200 is exposed to the inner space of the middle pipe 313.

In addition, the upper plate 312 is formed with a plurality of screw tabs 314 distributed.

The pipe pressurizing unit 320 is built into the binding casing 310 and includes an external pressurizing pipe body 321 that moves in the direction from the air injection nozzle 100 to the air supply pipe 200 by operation of the pressurizing operation unit 330, and an external pressurizing pipe body 321. An internal pressurizing pipe body 322, which is located inside the pressurizing pipe body 321 and whose diameter is narrowed by pressure caused by the movement of the external pressurizing pipe body 321, and an air supply pipe 200 located inside the internal pressurizing pipe body 322. ) and includes a supply pipe pressurizing pipe body 323 that is provided in a state surrounding the air supply pipe body 323 and pressurizes the air supply pipe 200 while narrowing the diameter by the pressure of the internal pressurizing pipe body 322.

The external pressurized pipe body 321, the internal pressurized pipe body 322, and the supply pipe pressurized pipe body 323 are each formed in a ring shape, and the inner pressurized pipe body 322 and the supply pipe pressurized pipe body 323 have a narrow diameter when the outer peripheral surface is pressurized. It may be composed of soft metal material. Of course, when the pressure is released, each is restored to its original state. That is, the force applied to the external pressurizing pipe body 321 by the WEDGE EFFECT is transmitted to the internal pressurizing pipe body 322, the force applied to the internal pressurizing pipe body 322 is transmitted to the supply pipe pressurizing pipe body 323, and the supply pipe pressurization The force applied to the pipe body 323 is transmitted to the air supply pipe 200. At this time, the air supply pipe 200 pressurizes and fixes the air injection nozzle 100 with a pressure generated at the Young's modulus (YOUNG MODULUS) ratio of the material.

Here, the supply pipe pressurizing pipe body 323 is formed in a cylindrical shape and can evenly pressurize the entire air supply pipe 200.

In addition, the internal pressurizing pipe body 322 and the supply pipe pressurizing pipe body 323 may be composed of a plurality of pieces formed in an arc shape. That is, since the external pressurizing pipe body 321 forms a circle when a plurality of pieces are connected to each other due to the pressure generated by moving from the air injection nozzle 100 in the direction of the air supply pipe 200, the pieces of the internal pressurizing pipe body 322 As they gather together, they pressurize the pieces of the supply pipe pressurizing pipe body 323, and as the pieces of the supply pipe pressurizing pipe body 323 gather together, they evenly pressurize the entire outer peripheral surface of the air supply pipe 200.

The upper end of the external pressurizing pipe body 321 is located directly below the screw tab 314 formed on the upper plate 312. Accordingly, the pressure control unit 330 coupled to the screw tab 314 rotates and presses the upper end of the external pressure pipe body 321, so that the external pressure pipe body 321 can be lowered.

In addition, the external pressurizing pipe body 321 is formed with a vertical length shorter than the length of the internal pressurizing pipe body 322, and an inner inclined surface 325 whose inner diameter narrows from the bottom to the top is formed on the inner circumferential surface, and the internal pressurizing pipe body 321 (322) is formed on the outer peripheral surface of the outer inclined surface (324) whose outer diameter widens from the top to the bottom.

Therefore, when the external pressurizing pipe body 321 is inserted into the internal pressurizing pipe body 322 and the inner inclined surface 325 is supported by contacting the outer inclined surface 324, the lower end of the external pressurizing pipe body 321 is spaced apart from the lower plate 311. do.

In this state, when the external pressurizing pipe body 321 is lowered, the entire outer side of the internal pressurizing pipe body 322 is pressed evenly, so that the diameter of the internal pressurizing pipe body 322 is narrowed. Of course, when the external pressurizing pipe body 321 is raised, the internal pressurizing pipe body 322 is expanded and restored to its original state.

Therefore, when the external pressurizing pipe body 321 is lowered by the pressurizing operation unit 330 while the inner inclined surface 325 of the external pressurizing pipe body 321 is in contact with the outer inclined surface 324 of the internal pressurizing pipe body 322, the internal pressurizing The pipe body 322 pressurizes the supply pipe pressurization pipe body 323. At this time, since the pressurized supply pipe pressurizing pipe body 323 pressurizes the outer peripheral surface of the air supply pipe 200, the outer peripheral surface of the air supply pipe 200 is also pressurized and the diameter is reduced to pressurize the outer peripheral surface of the air injection nozzle 100. That is, the air injection nozzle 100 is fixed to the air supply pipe 200 by the nozzle coupling portion 300.

In addition, the pipe pressurizing unit 320 is embedded in the binding casing 310 and includes an external pressurizing pipe body 321 that moves in the direction from the air injection nozzle 100 to the air supply pipe 200 by operation of the pressurizing operation unit 330. , located inside the external pressurizing pipe body 321 and surrounding the air supply pipe 200, and pressurizing the air supply pipe 200 while narrowing the diameter due to the pressure caused by the movement of the external pressurizing pipe body 321. Includes a pressurized pipe body (322).

Therefore, the pipe pressurizing unit 320 can be composed of only the internal pressurizing pipe body 322 and the external pressurizing pipe body 321 to pressurize the air supply pipe 200 while excluding the supply pipe pressurizing pipe body 323, so the configuration is simple. It can be done.

The pressurizing operation unit 330 may be composed of a bolt that is screwed to the screw tab 314 of the upper plate 312 and pressurizes the tube pressurizing unit 320.

Therefore, when the bolts of the pressure operation unit 330 that are respectively screwed to the screw tabs 314 of the upper plate 312 are tightened, the bolts descend and pressurize the entire top of the external pressure pipe body 321 evenly, so that the external pressure pipe body 321 ) goes down.

In this way, as the nozzle coupling unit 300 pressurizes the air supply pipe 200, the air injection nozzle 100 can be fixed to the air supply pipe 200 and used, and by operating the nozzle coupling unit 300, the air injection nozzle 100 can be used by high temperature. The deformed or damaged air injection nozzle 100 can be replaced by separating it from the air supply pipe 200.

In addition, as shown in Figures 8 to 10, in another embodiment of the binding casing 310, the lower plate 311 is fixed to the upper end of the air supply pipe 200, and the lower end of the middle pipe 313 is fixed to the lower plate 311. ) and the upper end of the middle pipe 313 is fixed to the upper plate 312. The upper plate 312 is not fixed to the air supply pipe 200 and is spaced upward from the top of the air supply pipe 200.

Therefore, since the pipe pressurizing portion 320 accommodated in the middle pipe body 313 directly pressurizes and fixes the air injection nozzle 100, the fixing force is increased and the fixed state of the air injection nozzle 100 can be firmly maintained. there is.

In addition, the nozzle pipe body 110 of the air injection nozzle 100 has a male thread 101 formed on its outer peripheral surface, and the air supply pipe 200 has a female thread 201 formed on its inner peripheral surface.

Therefore, since the air injection nozzle 100 is screwed to the air supply pipe 200 and is primarily fixed, it is secondarily fixed by the nozzle fastening part 300, so the binding force can be increased and the fixed state is solid. and can be maintained stably.

In this way, according to the present invention, it is possible to replace the air injection nozzle that is deformed by the high temperature generated in the fluidized bed combustion furnace in the process of supplying air to the fluidized bed combustion furnace of the fluidized bed boiler, so it is convenient to use and is applied to the field. Can be widely used.

As described above, although the present invention has been described with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalence of the claims to be described.

10: Fluidized bed combustion furnace 20: Air injection device
100: air injection nozzle 110: nozzle pipe body
101: male thread 120: nozzle head
121: nozzle hole 200: air supply pipe
201: female thread 300: nozzle coupling part
310: binding casing 311: lower plate
312: upper plate 313: middle pipe body
314: Screw tab 320: Pipe pressure section
321: External pressurized pipe body 322: Internal pressurized pipe body
323: Supply pipe pressurization pipe body 324: Outer slope
325: Inner slope 330: Pressure control unit

Claims (9)

An air injection nozzle (100) that sprays air to the lower part of the fluidized bed combustion furnace (10) in the fluidized bed boiler,
An air supply pipe (200) to which the air injection nozzle (100) is detachably connected and which supplies air to the air injection nozzle (100),
It includes a nozzle binding unit 300 that is provided in the air supply pipe 200 and binds the air injection nozzle 100 to maintain the air injection nozzle 100 inserted into the air supply pipe 200,
The nozzle coupling portion 300 is
A binding casing (310) through which the air supply pipe (200) is penetrated and fixed,
A tube pressurizing part 320 that pressurizes the air supply pipe 200 so that the air supply pipe 200 pressurizes and fixes the air injection nozzle 100 when built in the binding casing 310;
A nozzle binding device comprising a pressure operation unit 330 that operates the tube pressurization unit 320 so that the tube pressurization unit 320 pressurizes the air supply pipe 200.
delete In claim 1,
The binding casing (310) is
A lower plate 311 fitted and fixed to the lower part of the air supply pipe 200,
An upper plate 312 spaced upward from the lower plate 311 and fitted and fixed to the upper part of the air supply pipe 200,
A nozzle characterized in that it includes a middle pipe body (313) whose lower end is fixed to the outside of the lower plate (311) and the upper end of which is fixed to the outside of the upper plate (312) and has an internal space in which the pipe pressurizing portion (320) is accommodated. Binding device.
An air injection nozzle (100) that sprays air to the lower part of the fluidized bed combustion furnace (10) in the fluidized bed boiler,
An air supply pipe (200) to which the air injection nozzle (100) is detachably connected and which supplies air to the air injection nozzle (100),
It includes a nozzle binding unit 300 that is provided in the air supply pipe 200 and binds the air injection nozzle 100 to maintain the air injection nozzle 100 inserted into the air supply pipe 200,
The nozzle coupling portion 300 is
A binding casing (310) fixed to the upper part of the air supply pipe (200) in a communicating state,
A pipe pressing part 320 that presses the air injection nozzle 100 inserted into the air supply pipe 200 through the binding casing 310 while embedded in the binding casing 310, and
A nozzle binding device comprising a pressurizing operation unit 330 that manipulates the tube pressurizing unit 320 so that the tube pressurizing unit 320 presses the air injection nozzle 100.
In claim 4,
The binding casing (310) is
A lower plate 311 fixed to the upper part of the air supply pipe 200,
An upper plate 312 spaced upward from the lower plate 311,
A nozzle characterized in that it includes a middle pipe body (313) whose lower end is fixed to the outside of the lower plate (311) and the upper end of which is fixed to the outside of the upper plate (312) and has an internal space in which the pipe pressurizing portion (320) is accommodated. Binding device.
delete In claim 4,
The tube pressure part 320 is
An external pressurizing pipe body 321 that is built into the binding casing 310 and moves in the direction from the air injection nozzle 100 to the air supply pipe 200 by operation of the pressurizing operation unit 330,
It is located inside the external pressurizing pipe body 321 and is provided to surround the air supply pipe 200, and the diameter is narrowed by the pressure caused by the movement of the external pressurizing pipe body 321, and the internal pressure is applied to the air injection nozzle 100. A nozzle binding device comprising a pressurized pipe body (322).
In claim 7,
The external pressurizing pipe body 321 is formed with a vertical length shorter than the length of the internal pressurizing pipe body 322,
The external pressurizing pipe body 321 has an inner inclined surface 325 formed on the inner circumferential surface whose inner diameter narrows from the bottom to the top,
The internal pressurizing pipe body 322 is a nozzle binding device characterized in that an outer inclined surface 324 is formed on the outer circumferential surface whose outer diameter increases from the top to the bottom.
In claim 5,
The upper plate 312 is formed with a plurality of screw tabs 314 distributed,
The top of the external pressurizing pipe body 321 is located directly below the screw tab 314 formed on the upper plate 312,
The pressure operation unit 330 is a nozzle binding device characterized in that it is composed of a bolt that is screwed to the screw tab 314 of the upper plate 312 and pressurizes the tube pressurization unit 320.

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