KR101667593B1 - A control valve for cryogenic high pressure gas which having reinforced sealing member - Google Patents

Abstract

The present invention provides a control valve for cryogenic high-pressure gas having a sealing member with reinforced durability. The control valve for cryogenic high-pressure gas having a sealing member with reinforced durability comprises: a valve body (10) having a gas inlet passage (12) and a gas outlet passage (16) on both sides thereof; a bonnet (20) disposed on an upper portion of the valve body (10); a cage (30) which has a gas inlet hole (32) formed on one side thereof to communicate with the gas inlet passage (12) of the valve body (10) and a gas outlet hole (36) formed on the other side thereof to communicate with the gas outlet passage (16) of the valve body (10), and is mounted on a center flow passage (14) of the valve body (10); a plug (40) which has an opening/closing end (42) formed on a lower side thereof in a prescribed length, a plurality of vertical through holes (44) separated from each other, and an uneven groove (46) formed on an edge of an upper surface thereof in an annular shape, and is inserted into the cage (30); a pressing plate (50) which has an inclined surface (52) formed on an edge portion of an upper surface thereof and a plurality of second vertical through holes (54) communicating with the first vertical through holes (44) of the plug (40), and is fixed and mounted on the upper surface of the plug (40); a stem (60) positioned on a central axis of the bonnet (20), wherein one extended end thereof is fixed and mounted on a central axis of the plug (40); and a sealing member (70) comprising a carbon graphite ring (72) inserted along the uneven groove (46) of the plug (40) and a wave spring (74) seated on an upper portion of the carbon graphite ring (72).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control valve for cryogenic high pressure gas, which is equipped with a durability-

The present invention relates to a cryogenic ultra-high pressure gas control valve, and more particularly, to a control valve for cryogenic ultra-high pressure gas which is capable of maintaining the airtightness by further increasing the closed state of the valve by using the pressure of the gas filled in the pipe, Temperature ultra-high pressure gas control valve provided with a durability-enhanced airtightness maintaining body capable of maintaining stable airtightness.

Valves that control cryogenic ultra-high pressure gas are widely used in LNG carrier and aerospace applications and are specifically designed to operate in extreme environments. Such a valve must satisfy conditions such as good toughness, good weldability and workability, corrosion resistance to a fluid to be used in its material, and maintain excellent airtightness in a cryogenic environment and further ensure smooth operation.

However, most of the valves used in the field are not developed to be used under the conditions of cryogenic temperature and super high pressure, so that frequent gas leakage accidents occur, and explosion accident occurs due to valve damage or breakage. Among the proposed techniques to solve such a problem, there is Korean Patent No. 0978061.

This technique focuses on improving the technology between the plug and the seat which form the contact point while opening and closing the flow path inside the valve body. In other words, as shown in Fig. 3, by proposing a configuration in which the sheets 12 and 13 are arranged in the upper and lower portions of the plug 3 that opens the flow path inside the valve body, And more stable airtightness is maintained in a closed state.

However, when the valve is closed by the plug, the portion receiving the highest pressure in the valve body internal passage is a portion of the plug exposed in the direction of the gas inlet, and the plug receives a high pressure fluid pressure vertically. However, when the high pressure acts vertically on the plug portion, it is difficult to easily maintain the airtightness by simply arranging the sheet vertically and vertically. Therefore, an improvement strategy is needed.

Korean Patent No. 0929802, Korean Patent No. 0978061

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art, and it is an object of the present invention to provide a cryogenic super high pressure gas which can maintain the closed state of the valve even when the valve is frequently operated, Of the control valve.

In order to achieve the above object, the present invention provides a valve body (10) having a gas inlet (12) and a gas outlet (16) on both sides thereof; A bonnet 20 provided at an upper portion of the valve body 10; A gas inflow hole 32 formed at one side of the valve body 10 and communicating with the gas inflow path 12 of the valve body 10 and a gas vent hole 32 formed at the other side and communicating with the gas discharge path 16 of the valve body 10 A cage 30 provided on the central passage 14 of the valve body 10; A plurality of first vertical through holes 44 formed to be spaced apart from each other by a predetermined distance and a stepped groove 46 formed in an annular shape at a corner of the upper surface, A plug (40) inserted into the plug (30); And a plurality of second vertical through holes 54 formed so as to communicate with the first vertical through holes 44 of the plug 40 are provided on the upper surface of the plug 40, A pressure plate (50) coupled thereto; A stem 60 positioned on the central axis of the bonnet 20 and having an extended end fixedly coupled to the central axis of the plug 40; A hermetic container 70 made of a carbon graphite ring 72 inserted along the stepped groove 46 of the plug 40 and a wave spring 74 placed on the carbon graphite ring 70; A stainless steel ring 76 having a predetermined thickness and mediated between the carbon graphite ring 72 and the wave spring 74; And the present invention is characterized in that it includes the technical features.

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According to the present invention, a through-hole is formed in each of the plug and the pressure plate for raising and lowering the inside of the cage, and the valve is easily closed by the force of the high pressure gas flowing through the through hole pushing the pressure plate downward, The confidentiality can be maintained more completely.

Further, the present invention proposes a configuration in which a carbon graphite ring, a stainless ring, and a carbon graphite ring are disposed on one side of a plug, and presses them with the elastic force of a wave spring. By doing so, It is possible to easily maintain a stable airtight state for a long time even if abrasion occurs on the outer side of the holding means.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic cross-sectional view of a control valve for cryogenic ultra-high pressure gas according to the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control valve for cryogenic ultra-high pressure gas.
3 is a block diagram of a conventional control valve for ultra-low temperature ultra-high pressure gas.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

1 is a schematic cross-sectional view of a control valve for cryogenic ultra-high pressure gas according to the present invention. The valve body 10, the bonnet 20, the cage 30, the plug 40, , A stem (60), and a gas tight chamber (70). Each of these configurations will be described in detail.

A gas inflow passage 12 and a gas discharge passage 16 are provided on both sides of the valve body 10 and a central passage 14 communicating with the gas inflow passage 12 and the gas discharge passage 16, ).

A bonnet 20 is provided at an upper portion of the valve body 10. The bonnet 20 seals the central passage 14 of the valve body 10 and is tightly fastened to the valve body 10 by fastening means such as the bolts shown.

The cage 30 is a part for guiding the vertical movement of the plug 40 and is mounted on the central flow passage 14 of the valve body 10. Gas inflow holes 32 and gas discharge holes 36 are formed on both sides of the cage 30. The gas inlet hole 32 communicates with the gas inlet passage 12 and the gas outlet hole 36 communicates with the gas outlet passage 16.

The plug 40 is a portion that vertically ascends and descends along the inner surface of the cage 30 and opens and closes the flow path of the valve body 10. The plug 40 includes an open end 42, a first vertical through hole 44, a stepped groove 46, And is inserted into the cage 30. The open / close end 42 is protruded downward by a predetermined length as a means for opening / closing the gas inlet hole 32 and the gas outlet hole 36 of the cage 30. The first vertical through holes 44 are passages through which high-pressure gas moves, and a plurality of the vertical through holes 44 are formed at a predetermined interval. The stepped groove 46 is annularly formed on the upper surface corner portion of the plug 40, and the airtight holding body 70 is inserted.

The pressure plate 50 is fixedly coupled to the upper portion of the plug 40, and the inclined surface 52 and the second vertical through hole 54 are formed. The inclined surface 52 is preferably formed in an annular shape along the upper edge corner portion, and functions to allow the high-pressure gas to move easily. It is preferable that the second vertical through hole 54 is a moving passage for the high pressure gas and communicates with the first vertical through hole 44 of the plug 40. [ The platen can be tightly coupled to the plug by fastening means such as bolts.

The stem (60) is located on the center axis of the bonnet (20), and one end portion thereof is fixedly coupled to the central axis of the plug (40). With this arrangement, when the drive motor (not shown) is operated, the stem 60 vertically ascends and descends the plug 40. Further, since the pressure plate 50 is tightly coupled to the plug 40, when the plug 40 is vertically lifted and lowered by the operation of the stem 60, the pressure plate 50 also vertically moves up and down together.

The hermetic seal member 70 is a means for maintaining airtightness when the valve is in the closed state and is inserted into the stepped groove 46 of the plug 40. 2, the present invention proposes a case in which the hermetic holder 70 is made of a carbon graphite ring 72 and a wave spring 74. [

The carbon graphite ring 72 is inserted into the stepped groove 46 of the plug 40, and the outer surface portion of the carbon graphite ring 72 contacts the inner surface of the cage 30 to maintain airtightness. The wave spring 74 is a means for pressing the carbon graphite ring 72, and is formed in an annular shape, and a plurality of irregularities are formed. The vertical height between the floor and the valley of the wave spring 74 is preferably formed to be larger than the vertical height of the stepped groove 46.

That is, when the pressure plate 50 is coupled to the plug 40 in a state where the carbon graphite ring 72 and the wave spring 74 are inserted into the stepped groove 46 of the plug 40, The carbon graphite ring 72 is pressed with a predetermined force in a state in which the bottom surface of each of the troughs contacting the carbon graphite ring 72 is pressed. Accordingly, even if one side of the carbon graphite ring 72 is worn during the frequent opening and closing of the valve, as the wave spring 74 presses the carbon graphite ring 72 with a certain force, It is possible to maintain a stable airtightness in the fixed position of the valve 46. The wave spring 74 may be made of a metal having a predetermined thickness.

The present invention does not exclude the case where a stainless ring 76 having a predetermined thickness is added to the airtight container 70. The stainless steel ring 76 is preferably mediated between the wave spring 74 and the carbon graphite ring 74. As described above, when the stainless ring 76 is mediated, the elastic force by the wave spring 74 is transmitted to the stainless steel ring 76 of the plate-like structure, and the stainless ring 76 is inserted into the step groove 46, ) To the carbon graphite ring (74) in contact with the surface of the carbon graphite ring (74).

In other words, when the wave spring 74 directly contacts the carbon graphite ring 74, the elastic force is transmitted by a plurality of lines (the lower surface of each of the corrugations formed on the wave springs 74) A uniform elasticity force is transmitted through the surface through the stainless ring 76 to the carbon graphite ring 74 so that the carbon graphite ring 74 can maintain a more stable insertion state.

The operation configuration of the present invention having such a configuration will be schematically described with reference to the above description and FIG. 2 attached hereto.

If it is necessary to close the flow path of the valve while the high-pressure fluid moves freely through the valve, the drive motor operates according to the input signal of the control device not shown. When the drive motor is operated, the stem 60 is slowly lowered so that the open / close end 42 of the plug 40 gradually closes the gas inflow hole 32 and the gas discharge hole 36 of the cage 40 . When the stem 60 is completely lowered, the valve is closed and the high-pressure gas P is stagnated in the vicinity of the gas inflow path 12 of the valve body 10.

When the high-pressure gas stagnates in the space in the gas inlet path 12, some of the high-pressure gas due to the pressure causes the first vertical through-hole 44 of the plug 40 and the second vertical through- 54, and flows into the space of the central passage 14 of the valve body 10, more specifically, the space above the pressure plate 50. [

At this time, the carbon graphite ring 72 is inserted into the stepped groove 46 of the plug 40 and the outer surface portion of the carbon graphite ring 72 is pressed against the inner surface of the cage 30 while the wave spring 74 So that there is no outflow of gas through the space between the carbon graphite ring 72 and the cage 30.

Therefore, the gas sequentially introduced into the space above the pressure plate 50 presses the pressure plate 50 downward at a value equal to the gas pressure P stagnated in the vicinity of the gas inflow path 12. As a result, the closed state of the valve is maintained more solidly. That is, the portion of the central flow passage 14 of the valve body 10 is completely disconnected from the gas discharge passage 16, and the valve becomes more completely sealed.

As described above, according to the present invention, a high-pressure gas is introduced through a through-hole of a plug and a pressure plate to push the pressure plate at a constant force to easily maintain the closed state of the valve, A completely closed state of the valve can be realized by completely disconnecting the valve.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

10: Valve body 20: Bonnet
30: Cage 40: Plug
50: pressure plate 60: stem
70: gas tight body 72: carbon graphite ring
74: Wave spring 76: Stainless steel ring

Claims (2)

A valve body 10 having gas inflow paths 12 and gas discharge paths 16 on both sides thereof;
A bonnet 20 provided at an upper portion of the valve body 10;
A gas inflow hole 32 formed at one side of the valve body 10 and communicating with the gas inflow path 12 of the valve body 10 and a gas exhaust hole 32 formed at the other side and communicating with the gas exhaust path 16 of the valve body 10 A cage 30 provided on the central passage 14 of the valve body 10;
A plurality of first vertical through holes 44 formed to be spaced apart from each other by a predetermined distance and a stepped groove 46 formed in an annular shape at a corner of the upper surface, A plug (40) inserted into the plug (30);
And a plurality of second vertical through holes 54 formed so as to communicate with the first vertical through holes 44 of the plug 40 are provided on the upper surface of the plug 40, A pressure plate (50) coupled thereto;
A stem 60 positioned on the central axis of the bonnet 20 and having an extended end fixedly coupled to the central axis of the plug 40;
A hermetic container 70 made of a carbon graphite ring 72 inserted along the stepped groove 46 of the plug 40 and a wave spring 74 placed on the carbon graphite ring 72;
A stainless steel ring 76 having a predetermined thickness and mediated between the carbon graphite ring 72 and the wave spring 74;
Pressure ultra-high pressure gas control valve equipped with a durability-enhanced airtight container.
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