KR20230026647A - Wedged complex sealing gasket structure of cryogenic ball valve - Google Patents

Abstract

The present invention provides a wedge-type composite seal gasket structure of a cryogenic ball valve seat retainer to prevent a seal gasket inserted between a ball valve body and a seat retainer in a ball valve for cryogenic liquefied natural gas to prevent fluid leakage from being contracted by a cryogenic effect to leak fluid. The cryogenic ball valve (100) has a seat structure including a metallic ball (104), a non-metallic seat ring (105) coming in contact with the ball (104), a seat retainer (106) to retain the seat ring (105), an elastic member (108) pushing the seat retainer (106) toward the ball (104), and a wedge-type seal gasket (109, 129) inserted between a body (101) of the ball valve and the seat retainer (106). A seat ring coupling groove (1061) is horizontally formed at a position at which the seat ring (105) is coupled on the surface coming in contact with the ball (104). An elastic member holder mounting protrusion (1063) allowing an elastic member holder (107) to be mounted thereon is formed on the upper surface of the seat retainer (106) on the elastic member (108) side mounted on a body cap (102). A seal gasket mounting protrusion (1065) having a height higher than the elastic member holder mounting protrusion (1063) is formed on the upper surface of the seat retainer (106) on the ball (104) side of the elastic member holder mounting protrusion (1063).

Description

Cryogenic ball valve seat retainer wedge-shaped composite seal gasket structure {WEDGED COMPLEX SEALING GASKET STRUCTURE OF CRYOGENIC BALL VALVE}

The present invention relates to a sealing structure of a ball valve for cryogenic liquefied natural gas, and more particularly, in a ball valve for cryogenic liquefied natural gas, a seal gasket inserted between a ball valve body and a seat retainer to prevent fluid leakage is It relates to a wedge-shaped composite seal gasket structure that can be contracted under the influence of and prevented from leaking fluid.

The production process of natural gas (NG; Natural Gas) is similar to that of coal, and when oil is produced, it is produced by being mixed together, but most are produced separately. 80 ~ 85% of the main component of natural gas is methane (CH ₄ ) gas, and its use value as an energy source is highly evaluated due to the advantage that the content of pollutants is extremely low. However, since natural gas is in a gaseous state, it is difficult to store a large amount in one place, and it is difficult to transport it in large quantities except for transportation through pipelines. As a result, natural gas liquefaction technology has been developed to enable mass storage and remote mass manual operation, and is gradually increasing along with the increase in the proportion of natural gas use.

Natural gas with these characteristics is transported through pipes in a liquefied state at an ultra-low temperature of -196 ℃ for convenience of storage, and a ball valve used as a means to open and close the flow path of liquefied gas is attached to the seat retainer in contact with the ball. It is configured to maintain airtightness by a seat ring to be mounted and a seal gasket inserted between the valve body and the seat retainer.

1 is a cross-sectional view of a prior art ball valve 50.

As shown in Figure 1, the ball valve 50 of the prior art is coupled to the body 1, the ball 4 mounted on the inside of the body, and both sides of the body 1, together with the body 1, the ball 4 ) between the body cap 2 that rotatably supports the body cap 2, the seal gasket 9 that maintains airtightness between the body cap 2 and the ball 4, and between the body cap 2 and the ball 4 The seal gasket structure for fixing the seal gasket (9) maintaining airtightness, the body stud bolt (11) and body nut (12) for coupling and fixing the body (1) and the body cap (2), and the body (1) The lower cover 13 that shields the lower opening, the lower gasket 14 that maintains airtightness between the body `1 and the lower cover 13, and the ball 4 at the top of the lower cover 13 The lower bush 15 coupled between the outer periphery of the upper protrusion of the lower cover 13 and the concave groove of the lower part of the ball 4 so as to be rotatably coupled, and the ball for rotation of the ball 4 ( A valve stem (3) coupled to the upper part of 4), a valve stem bush (17) coupled to the outer circumference of the valve seat (3), and the outer periphery and body of the valve seat (3) The thrust bearing 16 coupled between the cap 2, the extend 18 coupled to the outer circumference of the valve seat bush 17 at the upper portion of the thrust bearing 16, and the upper portion of the thrust bearing 16 and the seat gasket 20 coupled between the contact surface of the body cap 2 and the seat retainer 6 on which the extend gasket 19 coupled between the bottom surface of the extender 18 and the seal gasket 9 are mounted consists of including

And the seal gasket structure for maintaining the airtightness of the ball valve 50 of the prior art is a non-metallic seat ring 5 having elasticity in contact with the metal ball 4 and a seat holding the seat ring 5 A body inserted to prevent leakage of fluid between the retainer 6, the spring 8 and spring guide 5 that assist the seat retainer 6, and the valve body 1 and the seat retainer 6 It is configured to include a cap gasket (10).

Since the seal gasket structure of the prior art ball valve 50 having the above structure is exposed to extremely low temperatures, curing shrinkage occurs with a commonly used type of O-ring, and the seat retainer 6 and the valve body 1 There is a problem in that it is difficult to prevent the leakage of the fluid because it is impossible to maintain the airtightness between them.

Republic of Korea Patent No. 20-0458102

Therefore, the technical problem of the present invention is to solve the above-mentioned problems of the prior art, even if the composite wedge-shaped seal gasket cures and shrinks under the influence of ultra-low temperature, the shape of the composite wedge-shaped seal gasket is deformed by the pressure of the fluid, thereby reducing the seat retainer To provide a wedge-shaped composite seal gasket structure for a cryogenic ball valve seat retainer that allows airtightness between the valve body and the valve body.

In addition, another technical problem of the present invention is to forcefully maintain the sealing perfectly by means of a spring and pressure, and to effectively prevent leakage of cryogenic fluid even if cured and shrunk by employing a fluororesin with excellent cold resistance for a composite wedge-shaped seal gasket. It is to provide a wedge-shaped composite seal gasket structure for a ball valve seat retainer for cryogenic use to prevent

In order to achieve the above technical problem, one embodiment of the present invention, a ball 104 of a metal material, a seat ring 105 of a non-metal material in contact with the ball 104, and holding the seat ring 105 A seat retainer 106 for the seat retainer 106, an elastic member 108 for pushing the seat retainer 106 toward the ball 104, and a wedge shape inserted between the seat retainer 106 and the body 101 of the ball valve In the cryogenic ball valve 100 having a seat structure including seal gaskets 109 and 129, the wedge-shaped seal gaskets 109 and 129 have a structure divided into two and are hardened by cryogenic temperature Even when contraction deformation occurs, it is configured to cause expansion deformation while being in close contact with each other by external pressure, so that even when the pressure of the fluid increases, it is configured to prevent leakage of fluid by tightly sealing between coupling parts. Cryogenic ball valve seat retainer provides wedge-type composite seal gasket structure

In the seat retainer 106, a seat ring coupling groove 1061 is formed in the horizontal direction at a position where the seat ring 105 is coupled among the surfaces in contact with the ball 104, and is seated on the body cap 102 An elastic member holder seating jaw 1063 on which the elastic member holder 107 is seated is formed on the upper surface of the seat retainer 106 on the side of the elastic member 108, and the ball ( 104), it is characterized in that a seal gasket seating step 1065 having a higher height than the elastic member holder seating step 1063 is formed on the upper surface of the seat retainer 106 side.

The wedge-shaped seal gasket 109 is a conical seal 1091 coupled between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107, and the seat The inner periphery of the body cap 2 such that one end is caught on the locking jaw formed at the end of the retainer 106 on the side of the ball 104 and the other end is engaged with the wedge portion 1093 of the conical seal 1091 It is characterized in that it comprises a lip seal 1095 coupled between the outer periphery of the seat retainer 6.

The conical seal 1091 is formed in a ring shape, and an end coupled to the lip seal 1095 is characterized in that it is formed as a wedge portion 1093 having a conical cross section.

The lip seal 1095 is formed in a ring shape, and at an end coupled to the wedge portion 1093 of the conical seal 109, a groove into which the wedge portion 1093 is inserted is formed along the circumference of the ring of the lip seal 1095 It is characterized in that it is configured to form a lip portion (1097).

The wedge-shaped seal gasket 129 is. Including an outer wedge-shaped seal 1291 and an inner wedge-shaped seal 1295 coupled so as to overlap each other between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107 It is characterized by being composed.

In the outer wedge-shaped seal 1291, the upper surface of the cross section is a straight line in close contact with the inner circumferential surface of the body cap 102, the side surface of the cross section in contact with the elastic member holder 107 is vertical, and the inner circumferential inclined surface is the bottom surface of the cross section. 1293 is characterized in that it is formed as a ring having a rectangular cross section with an upward slope toward the inner circumferential wedge-shaped seal 1295 side.

In the inner wedge-shaped seal 1295, the lower surface of the cross section is a straight line in close contact with the outer circumferential surface of the seat retainer 106, the surface of the cross section supported by the step of the seat retainer 106 is vertical, and the upper surface of the cross section The outer circumferential inclined surface 1297 is characterized in that it is formed as a ring having a rectangular cross section having an upward slope in the step direction of the seat retainer 106.

Embodiments of the present invention change the shape of the composite wedge-shaped seal gasket so that the shape of the composite wedge-shaped seal gasket is deformed by the pressure of the fluid even if the composite wedge-shaped seal gasket cures and shrinks under the influence of cryogenic temperature, so that the seat retainer and the valve body It provides an effect of remarkably improving the leakage prevention performance of the cryogenic fluid by allowing airtightness to be maintained between them.

In addition, the present invention forcibly maintains the sealing perfectly by means of a spring and pressure, and effectively prevents the leakage of cryogenic fluid even if it is cured and shrunk by adopting a material with excellent cold resistance such as fluororesin for the composite wedge-shaped seal gasket. It provides an effect that allows

1 is a cross-sectional view of a cryogenic ball valve 5 of the prior art.
2 is a cross-sectional view of a cryogenic ball valve 100 to which a wedge-shaped seal gasket for a cryogenic ball valve seat retainer according to an embodiment of the present invention is applied.
3 is a cross-sectional view of a ball valve seat retainer wedge-shaped seal gasket for cryogenic use according to an embodiment of the present invention.
4 is a cross-sectional view of a ball valve seat retainer wedge-shaped seal gasket for cryogenic use according to another embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and, therefore, is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, combined)" with another part, this is not only "directly connected", but also "indirectly connected" with another member in between. "Including cases where In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “include” or “have” are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

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

2 is a cross-sectional view of a cryogenic ball valve 100 to which a wedge-shaped seal gasket for a cryogenic ball valve seat retainer according to an embodiment of the present invention is applied.

2, the ball valve 100 is coupled to the body 101, the ball 104 mounted inside the body 101, and both sides of the body 101, together with the body 101 Body cap 102 rotatably supporting (104), seal gaskets 109 and 129 maintaining airtightness between body cap 102 and ball 104, body cap 102 and ball 4 ) The seal gasket structure for fixing the seal gaskets 109 and 129 maintaining the airtightness between the body stud bolt 111 and the body nut 112 for coupling and fixing the body 101 and the body cap 102 , the lower cover 113 for shielding the lower opening of the body 101, the lower gasket 114 for maintaining airtightness between the body 101 and the lower cover 113, and the upper part of the lower cover 113 The lower bush 115 coupled between the outer periphery of the upper protrusion of the lower cover 113 and the concave groove at the bottom of the ball 104 to rotatably couple the ball 104, and the rotation of the ball 104 A valve stem 103 coupled to the top of the ball 104 for operation, a valve stem bush 117 coupled to the outer circumference of the valve seat 103, and a valve seat 103 The thrust bearing 116 coupled between the outer periphery of the body cap 102, the extend 118 coupled to the outer circumference of the valve stem 117 at the top of the thrust bearing 116, and the thrust bearing Between the contact surface of the seat retainer 106 and the body cap 102 on which the extend gasket 119 and the wedge-shaped seal gaskets 109 and 129 are mounted between the upper part of the 116 and the lower surface of the extender 118 It is configured to include a seat gasket 120 coupled to.

In addition, the wedge-shaped seal gaskets 109 and 129 have two divided structures, so that even when curing shrinkage deformation occurs due to cryogenic temperatures, they are configured to cause expansion deformation while being in close contact with each other due to external pressure, Even when the pressure of a fluid such as natural liquefied gas transported from the inside increases, it is configured to prevent fluid leakage by tightly sealing between coupling parts. In addition, the wedge-shaped seal gaskets 109 and 129 are made of fluorine resin having excellent cold resistance, so that leakage of the cryogenic fluid can be effectively prevented even after curing and shrinkage.

3 and 4 show a wedge-shaped composite seal gasket structure to which the wedge-shaped seal gaskets 109 and 129 according to an embodiment of the present invention are applied.

Specifically, FIG. 3 is a cross-sectional view of a wedge-shaped seal gasket 109 of a cryogenic ball valve seat retainer according to an embodiment of the present invention. FIG. 3 (a) is a wedge-shaped composite seal gasket to which the wedge-shaped seal gasket 109 is applied. It is an enlarged view of part B of FIG. 2 having a structure, and FIG. 3 (b) is an enlarged view of the wedge-shaped seal gasket 109, which is part C of FIG. 3 (b).

As shown in (a) of FIG. 3, the seal gasket structure for maintaining the airtightness of the ball valve 100 is a non-metallic seat ring 105 having elasticity in contact with the metal ball 104, and a seat ring ( 105), a seat retainer 106, an elastic member (spring) 108 that assists the seat retainer 106, an elastic member (spring) holder 107, a body cap 102, and a seat retainer 6 ) and the elastic member holder 107 are inserted into the outer periphery of the seat retainer 106 to maintain airtightness between the wedge-shaped seal gasket 109 and the valve body 101 and the seat retainer 106 It is configured to include a body cap gasket 110 inserted to prevent leakage of fluid.

Among the surfaces of the seat retainer 106 in contact with the ball 104, a seat ring coupling groove 1061 is formed in a horizontal direction at a position where the seat ring 105 is coupled. In addition, an elastic member holder seat 1063 on which the elastic member holder 107 is seated is formed on the upper surface of the seat retainer 106 on the side of the elastic member 108 seated on the body cap 102. In addition, a seal gasket seating step 1065 having a higher height than the elastic member holder seating step 1063 is formed on the upper surface of the seat retainer 106 on the ball 104 side of the elastic member holder seating step 1063.

As shown in (b) of FIG. 3, the wedge-shaped seal gasket 109 has a conical shape coupled between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107. One end of the seal 1091 and the locking jaw formed at the end of the ball 104 side of the seat retainer 106 are caught, and the other end is engaged with the wedge portion 1093 of the conical seal 1091. It is configured to include a lip seal 1095 coupled between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6.

At this time, the conical seal 1091 is formed in a ring shape, and an end coupled to the lip seal 1095 is formed as a wedge portion 1093 having a conical cross section. And the lip seal 1095 is also formed in a ring shape, and at the end coupled to the wedge portion 1093 of the conical seal 109, a groove into which the wedge portion 1093 is inserted is formed along the circumference of the ring of the lip seal 1095 to form the lip portion 1097.

In the above-described wedge-shaped seal gasket 109, the conical seal 1091 is pressed toward the lip seal 1095 by the elasticity of the elastic member 108, so that the wedge portion 1093 is the lip portion 1097 of the lip seal 1095. By being inserted into the groove of and coupled, it is forcibly maintained to perfectly seal. Thereafter, when ultra-low temperature and high pressure are applied, the wedge portion 1093 exerts pressure to spread the lip portion 1097 to both sides, so that the outer and inner circumferential surfaces of the lip portion 1097 are the inner circumferential surface of the body cap 102 and the seat retainer 106 It is in close contact with the outer circumferential surface to prevent leakage of cryogenic fluid.

Figure 4 is a cross-sectional view of a ball valve seat retainer wedge-shaped seal gasket 129 for cryogenic use of another embodiment of the present invention, Figure 4 (a) has a wedge-shaped composite seal gasket structure to which the wedge-shaped seal gasket 129 is applied 2 is an enlarged view of part B, and FIG. 4 (b) is an enlarged view of the wedge-shaped seal gasket 129, which is part D of FIG. 4 (a).

As shown in (a) of FIG. 4, the seal gasket structure for maintaining the airtightness of the ball valve 100 is a non-metallic seat ring 105 having elasticity in contact with the metal ball 104, and a seat ring ( 105), a seat retainer 106, an elastic member (spring) 108 that assists the seat retainer 106, an elastic member (spring) holder 107, a body cap 102, and a seat retainer 6 ) and the elastic member holder 107 are inserted into the outer periphery of the seat retainer 106 to maintain airtightness between the wedge-shaped seal gasket 129 and the valve body 101 and the seat retainer 106 It is configured to include a body cap gasket 110 inserted to prevent leakage of fluid.

Among the surfaces of the seat retainer 106 in contact with the ball 104, a seat ring coupling groove 1061 is formed in a horizontal direction at a position where the seat ring 105 is coupled. In addition, an elastic member holder seat 1063 on which the elastic member holder 107 is seated is formed on the upper surface of the seat retainer 106 on the side of the elastic member 108 seated on the body cap 102. In addition, a seal gasket seating step 1065 having a higher height than the elastic member holder seating step 1063 is formed on the upper surface of the seat retainer 106 on the ball 104 side of the elastic member holder seating step 1063.

And the wedge-shaped seal gasket 129 overlaps each other between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107, as shown in (b) of FIG. It is configured to include an outer circumferential wedge-shaped seal 1291 and an inner circumferential wedge-shaped seal 1295 coupled so as to be retained.

In the outer wedge-shaped seal 1291, the upper surface of the cross section is a straight line in close contact with the inner circumferential surface of the body cap 102, the side surface of the surface in contact with the elastic member holder 107 is vertical, and the inner circumferential inclined surface of the bottom surface of the cross section Reference numeral 1293 is formed as a ring having a rectangular cross section with an upward slope towards the inner circumferential wedge-shaped seal 1295 side.

In addition, the inner wedge-shaped seal 1295 has a bottom surface of the cross section that is a straight line in close contact with the outer circumferential surface of the seat retainer 106, and the surface of the section supported by the step of the seat retainer 106 is vertical, and the upper surface of the cross section The outer circumferential inclined surface 1297 is formed as a ring having a rectangular cross section with an upward slope in the step direction of the seat retainer 106 .

The outer wedge-shaped seal 1291 and the inner wedge-shaped seal 1295 having the above configuration are formed between the body cap 102 and the seat retainer 106 so that the inner circumferential inclined surface 1293 and the outer circumferential inclined surface 1297 contact each other and overlap each other. It is inserted and coupled to the circumferential region.

As a result, when pressure is applied by the cryogenic fluid being transported, the inner circumferential inclined surface 1293 of the outer wedge-shaped seal 1291 climbs up the outer circumferential inclined surface 1297 of the inner wedge-shaped seal 1295 and is closely coupled. This will prevent fluid leakage.

Seal members applied to the present invention may be made of a material having high cold resistance and elasticity, such as fluororesin.

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted as being included in the scope of the present invention.

50, 100: ball valve
1, 101: body
2, 102: body cap
3, 103: valve seat
4, 104: ball
5, 105: seat ring
6. 106: seat retainer
1061: seat ring coupling groove
1063: elastic member holder seating jaw
7, 107: elastic member holder (spring holder)
8, 108: elastic member (spring)
9: seal gasket
109, 129: wedge-shaped seal gasket
1091: conical seal
1093: wedge
1095: lip seal
1097: lip
1291: outer wedge type seal
1293: Inner slope
1295: Inner wedge type seal
1297: outer circumferential slope
10, 110: body cap gasket
11, 111: body stud bolt
12, 112: body nut
13, 113: lower cover
14, 114: lower gasket
15, 115: lower bush
16, 116: thrust bearing
17, 117: valve stem bush
18, 118: extend
19, 119: extend gasket
20, 120: seat gasket

Claims (8)

A ball 104 made of metal, a seat ring 105 made of a non-metal material in contact with the ball 104, a seat retainer 106 for holding the seat ring 105, and the seat retainer 106 For cryogenic use having a seat structure including an elastic member 108 pushing toward 104 and wedge-shaped seal gaskets 109 and 129 inserted between the seat retainer 106 and the body 101 of the ball valve In the ball valve 100,
The wedge-shaped seal gaskets 109 and 129 have two divided structures, so that even when curing shrinkage deformation occurs due to cryogenic temperatures, they are configured to cause expansion deformation while being in close contact with each other by external pressure, so that the pressure of the fluid Cryogenic ball valve seat retainer wedge-type composite seal gasket structure, characterized in that it is configured to prevent leakage of fluid by tightly sealing between coupling parts even when it is large. The method of claim 1, wherein the seat retainer 106,
Among the surfaces in contact with the ball 104, a seat ring coupling groove 1061 is formed in a horizontal direction at a position where the seat ring 105 is coupled, and a seat on the side of the elastic member 108 seated on the body cap 102. An elastic member holder seat 1063 on which the elastic member holder 107 is seated is formed on the upper surface of the retainer 106, and the seat retainer 106 on the ball 104 side is formed on the elastic member holder seat 1063. ) Cryogenic ball valve seat retainer wedge-type composite seal gasket structure, characterized in that the seal gasket seating jaw 1065 having a higher height than the elastic member holder seating jaw 1063 is formed on the upper surface of the ). The method of claim 1, wherein the wedge-shaped seal gasket (109),
A conical seal 1091 coupled between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107, and the ball 104 side of the seat retainer 106 Between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so that one end is caught on the locking jaw formed at the end and the other end is engaged with the wedge portion 1093 of the conical seal 1091 Cryogenic ball valve seat retainer wedge-shaped composite seal gasket structure, characterized in that it comprises a lip seal (1095) coupled to. The method of claim 3, wherein the conical seal (1091),
It is formed in a ring shape, and the end coupled to the lip seal 1095 is formed as a wedge portion 1093 having a conical cross section. The method of claim 4, wherein the lip seal (1095),
It is formed in a ring shape, and at the end of the conical seal 109 coupled to the wedge portion 1093, a groove into which the wedge portion 1093 is inserted is formed along the circumference of the ring of the lip seal 1095 to form a lip portion 1097 Cryogenic ball valve seat retainer wedge-shaped composite seal gasket structure, characterized in that configured. The wedge-shaped seal gasket (129) according to claim 3.
Including an outer wedge-shaped seal 1291 and an inner wedge-shaped seal 1295 coupled so as to overlap each other between the inner periphery of the body cap 2 and the outer periphery of the seat retainer 6 so as to be pressed by the elastic member holder 107 Cryogenic ball valve seat retainer wedge-shaped composite seal gasket structure, characterized in that configured. The method of claim 6, wherein the outer wedge-shaped seal (1291),
The upper surface of the cross section is a straight line in close contact with the inner circumferential surface of the body cap 102, the side surface of the surface in contact with the elastic member holder 107 is vertical, and the inner circumferential inclined surface 1293, which is the bottom surface of the cross section, is the inner wedge-shaped seal 1295 ) Cryogenic ball valve seat retainer wedge-type composite seal gasket structure, characterized in that formed by a ring having a rectangular cross section with an upward slope to the side. The method of claim 6, wherein the inner circumferential wedge-shaped seal (1295),
The bottom surface of the cross section is a straight line in close contact with the outer circumferential surface of the seat retainer 106, the surface of the cross section supported by the step of the seat retainer 106 is vertical, and the outer circumferential inclined surface 1297, which is the upper surface of the cross section, is the seat retainer ( 106) Cryogenic ball valve seat retainer wedge-type composite seal gasket structure, characterized in that formed by a ring having a rectangular cross section with an upward slope in the step direction.

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