KR100892118B1 - Poppet damper in exhaust gas duct - Google Patents

Abstract

A poppet damper of an exhaust gas duct is provided to improve the airtight property as the regular power can operate on the whole contact surface between a packing chamber and blade. A poppet damper of an exhaust gas duct comprises: a packing chamber(12) installed within a duct; a blade(11) contacting to the packing chamber; an actuator(13) providing the power for open and close operation while supporting the blade; a ball(16) mounted on an end part of shaft; a ball mounting groove(15) located in the upper side of blade; and a ball cap(17) in which the top spherical surface of ball is located on the top of the ball mounting groove.

Description

Poppet damper in exhaust gas duct}

The present invention relates to a poppet damper of the exhaust gas duct, and more particularly, to a poppet damper for controlling the flow of gas discharged from a boiler or an incinerator.

In general, a duct is required as a means for controlling the high-temperature exhaust gas emitted from various fluids in the gaseous state, such as a boiler or an incinerator, generated at an industrial site. Dampers are installed in the

When handling fluids that are chemically unstable or hazardous to the environment, special attention should be paid to the tightness of the duct.

1 is a cross-sectional view showing a poppet damper of a conventional exhaust gas duct.

As shown in FIG. 1, the openable blade 110 of the poppet damper 100 is located on the packing chamber 120 disposed in the gas flow control region in the exhaust gas duct 150, and the blade 110. ) Is supported in the form of being connected to the shaft 140 operated by the actuator 130.

Here, reference numeral 160 denotes a joint connecting the shaft and the blade.

Accordingly, the gas flow is controlled by the opening and closing operation of the blade when the actuator is operated.

However, the conventional poppet damper has several disadvantages as follows.

First, many problems are exposed in the connection method between the blade and the shaft.

For example, since the blade and the shaft is a fixed connection type coupled by a joint, when one side is in contact with the other side is not in close contact with the phenomenon occurs that the airtight is not completely made.

Secondly, since the contact between the blade and the packing seal is face-to-face contact, when foreign matter adheres to the face, perfect airtightness cannot be expected.

Third, in the case of the material of the packing seal, since materials such as graphite, teflon, and viton are used, there is a problem that the material must be changed according to the temperature and pressure of the gas flow.

In addition, when the pressure is high, fine leakage occurs in the tissue of the yarn, and if 100% airtightness is required, problems may occur.

Since the above materials can be used only at a maximum temperature of 500 ° C or below, they cannot be used at higher temperatures.

Accordingly, an object of the present invention is to provide a poppet damper that improves the fixation of the blade and the shaft to a ball connection structure so that an even force can be applied between the blade and the packing seal as a whole.

In addition, another object of the present invention is to improve the contact method of the blade and the packing seal to the inclined surface contact method so that it can be easily removed even when attaching foreign matter and to provide a poppet damper that can obtain a large airtight effect with a small force. There is this.

In addition, the present invention has another object to provide a poppet damper that can further improve the airtightness, such as to improve the material of the packing seal to a metal seal material to maintain the airtight of 100% even at high pressure and temperature.

Poppet damper provided in an embodiment of the present invention to achieve the above object is to provide a power for the opening and closing operation while supporting the blade by using a packing seal, the opening and closing blades in contact with the packing seal, the shaft is installed in the duct Including an actuator and the like, a ball seating groove is formed on an upper surface of the blade, and a ball received in the ball seating groove is mounted at an end of the shaft, and the blade and the shaft are coupled to the ball connecting structure.

Here, in the case of the blade it is preferable to be in contact with the interlocking form is fitted over the entire circumference of the inner circumferential surface of the packing seal through the inclined peripheral surface.

In addition, the material of the packing seal in contact with the blade side may be applied to the material of the metal seal.

Poppet damper provided by the present invention has the following advantages.

First, since the blade and the shaft are fixed in the form of balls, even if one side is contacted first, the blades can freely move at regular intervals, so that an even force can be applied to the entire contact surface between the blade and the packing seal. Confidentiality can be secured.

Second, since the contact between the blade and the packing seal is inserted while maintaining a constant angle, even if foreign matter is attached to the contacting surface can be pushed out while contact can be maintained to maintain a perfect air tightness, especially in the form of a wedge As a result, a large airtight effect can be expected with a small force.

Third, because the material of the metal seal is used, 100% airtightness can be maintained even under high pressure and temperature conditions, and the metal seal can be used up to 700 ℃ temperature, so there is no hassle due to the replacement of the seal and the period of use is also semi-permanent. This can be called.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 are perspective views showing the poppet damper according to an embodiment of the present invention.

2 and 3, the poppet damper 10 is installed in the duct to be in contact with the blade 11, the seal chamber 12 is located in the duct and is opened and closed to contact the packing chamber 12. Blade 11 for controlling the gas flow through the actuator, the actuator 13 is installed on the inside of the duct or the outside of the duct to move the blade 11 and connecting between the actuator 13 side and the blade 11 side Shaft 14 and the like.

The actuator 13 may apply a cylinder or the like as a means for moving the blade 11.

The actuator 13 may be installed inside or outside the duct. In one embodiment of the present invention, the actuator 13 may be installed perpendicularly to the outside of the duct, specifically, the upper portion of the damper body 21 connecting the duct to the duct.

One end of the shaft 14 is connected to the rod of the actuator 13 installed as described above, and the other end of the shaft 14 may extend to the inside of the valve body 21 to which the blade 11 belongs.

The blade 11 has a disc-shaped body and is supported by a structure connected to the shaft 14.

In particular, the blade 11 is coupled to the shaft 14 side by the ball connection structure is to allow a free movement at a predetermined interval.

To this end, the ball seating groove 15 is formed in the center of the upper surface of the blade 11, the ball 16 is mounted on the end of the shaft 14, the ball 14 at this time is the ball seating groove 15 By being coupled in the form accommodated in), the blade 11 and the shaft 14 may be coupled in a ball connection structure.

More specifically, the lower spherical surface of the ball 16 is accommodated in the ball seating groove 15, the ball cap 17 of the shape surrounding the upper spherical surface from the ball upper side is installed on the blade 11 side, 16 may be coupled to the structure that is prevented from being removed upward by the upper ball cap 17 in the state accommodated in the ball seating groove (15).

At this time, the inner surface of the ball cap 17 is a spherical surface for the smooth rolling motion of the ball, it is installed in a structure fixed to the blade 11 through the bolt fastening.

Accordingly, by using the movement of the ball 16, the blade 11 can freely move at regular intervals, and eventually, even if one surface is contacted first, the other surfaces may naturally contact through the free movement, An even force may act over the entire contact surface between the 11 and the packing seal 12.

In addition, the present invention provides a form in which the blade 11 and the packing seal 12 are fitted while maintaining a constant angle.

To this end, the circumferential surface of the blade 11 is an inclined circumferential surface 18 in the form of decreasing diameter toward the bottom, the inner circumferential surface of the packing seal 12 by using the inclined circumferential surface 18 It can be contacted in an interlocked form while being fitted over its entire circumference.

Since the blade 11 is inserted from the top down through the inclined circumferential surface 18, even if foreign matter is attached to the contacting surface can be inserted while pushing out, the problem of leakage due to foreign matter can be completely excluded.

In addition, since the inclined circumferential surface 18 of the blade 11 can be exerted from the top to the bottom, the wedge action can be exerted, so that a large airtight effect can be obtained with a small force.

At this time, the inner circumferential surface of the packing seal 12 in contact with the inclined circumferential surface 18 side of the blade 11 preferably has the same inclination angle as that of the inclined circumferential surface 18 of the blade 11. .

In addition, the present invention provides a packing seal 12 made of a material of a metal seal.

By using the material of the metal seal, it is possible to compensate for the problem of changing the material according to the temperature and pressure of the gas flow.

In addition, even under high pressure and temperature conditions, the metal seal can exhibit 100% airtight performance.

In the case of the metal seal material packing seal 12 provided by the present invention, since the maximum temperature can be used up to 700 ° C., there is no hassle due to the replacement of the seal, and the expiration date is also semi-permanent.

In addition, although the conventional packing yarn has a vulnerability in which a fine leak occurs as a form of weaving thread tissue, in the case of the metal seal material of the present invention, such a fine leak problem can be completely excluded.

4 is a cross-sectional view showing a state of use of the poppet damper according to an embodiment of the present invention.

As shown in FIG. 4, a packing seal 12 is installed toward the gas inlet 19 of the valve body 21, and the blade 11 is provided with respect to the gas inlet 19 and the gas inlet 19. It moves in the space between the gas outlet ports 20 which are 90 degree-direction.

The opening of the gas flow is made by the reverse operation of the actuator 13.

That is, the gas flow is opened as the blade 11 moves upward and falls from the packing chamber 12 side by the reverse operation of the actuator 13.

The closing of the gas flow is effected by the forward operation of actuator 913.

That is, the blade 11 moves downward by the forward operation of the actuator 13 and contacts the packing chamber 12 side, thereby closing the gas flow.

At this time, when the blade 11 and the packing seal 12 in contact with each other, the ball 16 can maintain a uniform contact state over the entire contact surface. At the same time, the foreign body can be pushed out by the wedge action, thereby maintaining tighter airtightness.

Thus, 100% complete airtightness of the contact portion between the blade and the packing seal can be secured.

1 is a cross-sectional view showing a poppet damper of a conventional exhaust gas duct.

Figure 2 is an exploded perspective view showing a poppet damper according to an embodiment of the present invention

3 is a perspective view showing a combined poppet damper according to an embodiment of the present invention

4 is a cross-sectional view showing a state of use of the poppet damper according to an embodiment of the present invention

<Description of the symbols for the main parts of the drawings>

10: poppet damper 11: blade

12: packing seal 13: actuator

14: shaft 15: ball seating groove

16: ball 17: ball cap

18: inclined circumferential surface 19: gas inlet

20 gas outlet 21 valve body

Claims (5)

The packing chamber 12 installed in the duct, the opening and closing blade 11 in contact with the packing chamber 12, and the shaft 14 to support the blade 11 while providing power for the opening and closing operation In the poppet damper comprising an actuator 13, A ball 16 is mounted at an end of the shaft 14, and a ball seating groove 15 is formed on an upper surface of the blade 11 to accommodate a lower spherical surface of the ball 16, and the ball seating groove ( The upper portion of the ball 15 is provided with a ball cap 17 is accommodated in the upper sphere of the ball 16 is coupled to the blade 11 and the shaft 14 in a ball connection structure, the blade 11 is inclined Poppet damper of the exhaust gas duct, characterized in that the contact through the circumferential surface 18 in the form of interlocking the entire circumference of the inner peripheral surface of the packing seal 12 having the same inclination angle. delete delete delete The poppet damper of claim 1, wherein the material of the packing chamber 12 in contact with the blade 11 side is made of a metal thread.

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