KR20130062035A - Valve for improving airtightness efficiency - Google Patents

Abstract

PURPOSE: A valve for improving airtightness is provided to minimize deformation and damage to the valve using a metal seal and to continuously prevent the leakage of fluid in the poor conditions of high temperature and high pressure. CONSTITUTION: A valve for improving airtightness comprises a cage(20) and a port(60). The cage has an opening(21) formed inside a body with an inlet port and an outlet port. The port ascends and descends inside the cage. A ring-shaped metal seal is arranged between the cage and the port to prevent the leakage of fluid.

Description

Valve for improving airtightness efficiency

The present invention relates to a valve, and relates to a valve for improving the airtight performance to ensure that the leakage of the fluid is continuously smooth even under poor conditions of high temperature and high pressure.

The flow path of the fluid is provided with a valve to adjust the flow amount and flow pressure of the fluid.

At this time, the valve has a variety of structures and manners, but basically by adjusting the opening or closing of the pipeline by the operating member by opening or closing the pipeline formed on the body can be adjusted the flow amount and flow pressure of the fluid. It was.

On the other hand, one of the valves is a flow control valve having a body, a cage, and a port.

As described above, the flow control valve having the body, the cage, and the port may adjust the flow rate of the cage by adjusting the opening degree of the cage as the port moves up and down at the center of the cage.

At this time, the cage and the port can be in close contact with the seal (Seal).

Therefore, it was possible to prevent the fluid from leaking into the gap between the cage and the port by the seal.

However, the conventional seal is made of Teflon or carbon-containing Teflon, so the adhesiveness is excellent, but if the port is repeatedly raised and lowered, wear is easily performed, and thus the cage and the port cannot be intimately contacted with each other as the period of use increases. There is a problem that can leak, especially when the fluid flowing into the body is a high temperature and high pressure can be damaged in a short time due to the nature of the material can not be in close contact between the cage and the port can leak fluid There was a problem.

For this reason, the relevant field is trying to develop a valve for improving the airtight performance so that the leakage of the fluid can be continuously smoothly under the harsh conditions of high temperature and high pressure, but until now, the results have not been satisfactory. to be.

The present invention has been proposed in view of the above situation, and as the conventional yarn is made of Teflon or carbon-containing Teflon, the characteristics of the material are easily damaged under poor conditions of high temperature and high pressure, thereby preventing the leakage of fluid. It is an object of the present invention to provide a valve for improving airtight performance.

Valve for improving the airtight performance according to the present invention for achieving the above object,

In the valve in which the opening for the inlet and outlet of the fluid is provided inside the body formed with the inlet and outlet, the port in the cage is raised and lowered,

The inner surface of the ring-shaped metal seal is formed between the cage and the port is a rounded bent portion is provided with the rounded bent portion of the metal seal is characterized in that to prevent the leakage of fluid by close contact around the port outer surface.

Here, the metal seal is characterized in that it is positioned on the top of the cage is seated on the seating jaw of the guide ring coupled to the top of the cage.

The metal seal is fixed on the cage by the retainer.

And it is characterized in that the inclined surface is provided to the upper end of the port and gradually protrudes outward.

The valve for improving the airtight performance according to the present invention, the inner circumferential surface of the metal seal is provided with a rounded bent portion, the upper end of the port is provided with an inclined surface that is gradually projected outwards upwards, deformed due to the material characteristics of the metal seal and In addition to minimizing damage, the round bent portion of the metal seal flows under pressure during the lifting and lowering of the port, and comes into close contact with the outer surface of the port. It works.

1 is an exploded perspective view for explaining the structure of the valve for improving the airtight performance according to the present invention
Figure 2 is a cross-sectional view of the coupling state for explaining the structure of the valve for improving the airtight performance according to the present invention
Figure 3 is a cross-sectional view for explaining the structure of the metal seal in the valve for improving the airtight performance according to the present invention
Figure 4 is a perspective view for explaining the structure of the guide ring in the valve for improving the airtight performance according to the present invention
Figure 5 is an operating state diagram for preventing fluid leakage through the metal seal in the valve for improving the airtight performance according to the present invention

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

1 and 2, the valve A for improving the airtight performance according to the present invention includes a body 10, a cage 20, a guide ring 30, a metal seal 40 and And a retainer 50 and a port 60.

The body 10 is the outlet 11 and the inlet 12 is formed.

Since the body 10 is the same as the body of a conventional valve, detailed description of the structure and operation is omitted.

The cage 20 is formed with an opening 21 for the inflow and outflow of the fluid.

In the cage 20, the opening 21 is preferably provided radially around the lower end.

Since the opening 21 of the cage 20 is provided radially around the lower end of the cage 20, the inflow and outflow of the fluid can be made through the opening 21 regardless of the direction.

On the other hand, the seat ring 22 is coupled to the bottom of the cage 20.

The seat ring 22 is coupled to the bottom of the cage 20 so that the cage 20 can be stably positioned on the body 10.

At this time, the gasket 23 is coupled to the top and bottom of the seat ring 22.

As the gasket 23 is coupled to the top and bottom of the seat ring 22, airtightness can be maintained between the cage 20 and the seat ring 22 and between the seat ring 22 and the body 10.

The guide ring 30 is coupled to the top of the cage 20, the mounting jaw 31 is provided on the inner side.

The seating jaw 31 of the guide ring 30 is preferably formed with a groove 32 extending from the lower end as shown in FIG.

A groove 32 is formed in the seating jaw 31 of the guide ring 30 so that fluid flowing through the groove 32 may be applied to the inner surface of the metal seal 40 seated on the guide ring 30. It becomes possible.

At this time, the groove 32 formed in the seating jaw 31 of the guide ring 30 is preferably provided radially in the seating jaw 31.

Since the groove 32 formed in the seating jaw 31 of the guide ring 30 is radially provided in the seating jaw 31, the inflow of fluid through the groove 32 is biased to a specific section of the seating jaw 31. It can be prevented.

The metal thread 40 is in the form of a ring, and the rounded bent portion 41 is provided on the inner side.

The upper end of the round bent portion 41 of the metal seal 40 is preferably provided with an extension portion 42 extending to the outside as shown in FIG.

As the extension part 42 extending outward is provided at the upper end of the round bent part 41 of the metal thread 40, the extension part 42 is seated on the seating jaw 31 of the guide ring 30. The metal seal 40 can be stably positioned on the 30.

On the other hand, the metal thread 40 is preferably made of a thin plate.

As the metal seal 40 becomes a thin plate, the rounded bent portion 41 may flow as the pressure is applied to the rounded bent portion 41.

The retainer 50 is positioned above the metal chamber 40, and a crimping surface 51 is provided on the bottom surface thereof in contact with the upper surface of the metal chamber 40.

In the retainer 50, the width of the crimp surface 51 is preferably larger than the width of the extension part 42 of the metal seal 40.

Since the width of the crimping surface 51 of the retainer 50 is larger than the width of the extension portion 42 of the metal thread 40, the entire mortar chamber 40 is uniformly made through the crimping surface 51 of the retainer 50. It can be crimped.

The port 60 is raised and lowered in the cage 20.

Since the lifting and lowering of the port 60 is performed according to the operation of lifting and lowering means (not shown) such as an actuator, detailed description of the lifting and lowering of the port 60 is omitted.

At this time, of course, the port 60 is provided with a stamp 61 penetrating through the bonnet 13, which is a part of the body 10.

The port 60 is provided with a stamp 61 penetrating through the bonnet 13, which is a part of the body 10, so that the stem 61 is connected to a lifting means such as an actuator. The lifting and lowering of 60 can be made.

On the other hand, the upper end of the port 60 is preferably provided with an inclined surface 62 that is directed upward and gradually outward.

The inclined surface 62 which is upwardly protruded upward and protrudes outward is provided at the upper end of the port 60 so that the contact between the port 60 and the metal sheet 40 may be intimately made by the inclined surface 62.

The port 60 is preferably provided with a through hole 63 extending vertically.

Since the through hole 63 which is perpendicular to the port 60 is provided, the fluid can flow through the through hole 63, so that the pressure on the port 60 when the port 60 descends can be adjusted. .

And it is preferable that the piston ring 64 is provided on the outer peripheral surface of the upper end of the port 60.

Since the piston ring 64 is provided on the upper outer circumferential surface of the port 60, the piston ring 64 may be in close contact with the inner circumferential surface of the retainer 50, so that airtightness may be maintained between the inner circumferential surface of the retainer 50 and the outer surface of the port 60. It becomes possible.

When the leakage of the fluid through the valve (A) for improving the airtight performance according to the present invention as described above in detail.

In the present invention, the upper part of the round bent part 41 of the metal thread 40 is provided with an extension part 42 extending outward, and the extension part 42 of the metal thread 40 is formed in the guide ring 30. When placed on the seating jaw 31, the metal thread 40 can be stably positioned on the guide ring 30.

Therefore, when the guide ring 30 on which the metal seal 40 is seated is coupled to the upper end of the cage 20, the metal seal 40 may be positioned on the upper portion of the cage 20.

At this time, the metal seal 40 is in a state capable of flowing on the guide ring 30, but the extension portion 42 of the metal seal 40 is pressed by the pressing surface 51 formed on the bottom of the retainer 50, the metal The seal 40 may be fixed to the cage 20 above.

When the lowering of the port 60 is made in the cage 20 by the operation of the lifting means in the above state, the outer surface of the port 60 is in contact with the methyl chamber 40.

That is, the rounded bent portion 41 of the metal thread 40 is protruded into the cage 20, and the rounded bent of the metal thread 40 when the port 60 moves up and down in the cage 20. The tip of the portion 41 comes into contact with the outer surface of the port 60.

Accordingly, the leakage of fluid through the gap between the inner surface of the cage 20 and the outer surface of the port 60 may be achieved by the metal seal 40.

In the above process, the rounded bent portion 41 of the metal seal 40 is to flow as the pressure is reduced.

In the present invention, the upper end of the port 60 is provided with an inclined surface 62 which is directed upward and gradually protrudes outwards, when the uppermost part of the port 60 comes into contact with the rounded bent portion 41 of the metal thread 40, the round is rounded. Since pressure is exerted from the outside of the bent portion 61, the metal seal 40 may be damaged.

However, in the present invention, since the metal seal 40 is made of a thin plate, the rounded bent portion 41 flows when pressure is applied to the rounded bent portion 41, so that the rounded bent portion is in contact with the top of the port 60. 41) When pressure is applied from the outside, the rounded bent portion 41 flows inward.

Therefore, when the metal sheet 40 is adjacent to the uppermost end of the port 60, the rounded bent portion 41 flows inward as shown in FIG. 5A and maintains close contact with the outer surface of the upper end of the port 60. Therefore, the leakage of the fluid can be achieved.

On the other hand, the portion below the upper end of the port 60 is smaller in diameter than the upper end, so a gap may occur between the tip of the round bent portion 41 of the metal sheet 40 and the outer surface of the port 60.

However, in the present invention, the seating jaw 31 of the guide ring 30 has a groove 32 extending from the bottom to the top thereof to be radially formed so that the flow of fluid through the groove 32 may be performed. Since the fluid introduced into the seating jaw 31 is exerted a pressure inside the round protrusion piece 41 of the metal sheet 40, the round protrusion piece 41 flows outward.

Therefore, when the metal sheet 40 is adjacent to the lowermost portion of the port 60, as shown in FIG. 5B, the rounded bent portion 41 flows outward and the outer surface of the portion below the uppermost portion of the port 60. Since it keeps in intimate contact with the fluid it is possible to prevent the leakage of the fluid.

As described above, in the valve A for improving the airtight performance according to the present invention, the rounded bent portion 41 is provided on the inner circumferential surface of the metal chamber 40, and the upper portion of the port 60 faces upwards. The inclined surface protruding outward is provided, the deformation and damage is minimized due to the material properties of the metal seal 40, as well as the rounded bent portion 41 of the metal seal 40 in the process of lifting and lowering the port 60 It flows by and is in intimate contact with the outer surface of the port, it is possible to smoothly prevent the leakage of fluid even in the harsh conditions of high temperature and high pressure.

Since the present invention as described above is not limited to the above-described embodiments, it can be changed within the scope not departing from the gist of the present invention claimed in the claims, such changes are within the claims described.

10 body 11 outlet
12 inlet 13 bonnet
20: cage 21: opening
22: seating 23: gasket
30: guide ring 31: seating jaw
32: groove 40: metal seal
41: round bend 42: extension
50: retainer 51: crimp surface
60: port 61: stamp
62: inclined surface 63: through hole
64: piston ring A: valve

Claims (10)

In the valve in which the opening for the inlet and outlet of the fluid is provided inside the body formed with the inlet and outlet, the port in the cage is raised and lowered,
A ring-shaped metal seal having a rounded bent inner portion between the cage and the port is provided so that the rounded bent portion of the metal seal adheres around the outer surface of the port to prevent leakage of fluid. valve. The method of claim 1,
The metal seal is seated on the seating jaw of the guide ring coupled to the top of the cage valve for improving the airtight performance, characterized in that located on the top of the cage. The method of claim 2,
The seating jaw of the guide ring is a valve for improving the airtight performance, characterized in that a groove extending from the bottom to the top is formed. The method of claim 3,
The groove is a valve for improving the airtight performance, characterized in that formed in the mounting jaw radially. The method of claim 1,
The metal seal is a valve for improving the airtight performance, characterized in that fixed to the top of the cage by a retainer. The method of claim 5,
The retainer is a valve for improving the airtight performance, characterized in that the bottom surface is provided with a pressing surface in contact with the upper surface of the metal seal. The method of claim 1,
Valve for improving the airtight performance, characterized in that the extension extending outward is provided on the upper end of the round bent portion of the metal seal. The method of claim 1,
Valves for improving the airtight performance, characterized in that the inclined surface is provided to the upper end of the port and gradually protrudes outward. The method of claim 1,
A valve for improving the airtight performance, characterized in that the through hole is provided perpendicular to the port is provided. 10. The method according to claim 8 or 9,
A valve for improving the airtight performance, characterized in that the piston ring in close contact with the inner peripheral surface of the retainer is provided on the upper outer peripheral surface of the port.

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