KR20230090837A - Cryogenic valve with check valve function - Google Patents

Abstract

The present invention relates to a valve body having an inlet, an outlet, and a flow path; a bonnet connected to an upper portion of the valve body, a gland maintained with a handle on the upper portion of the bonnet, and an operating shaft connected to the handle and protruding downward; a valve stem whose lower end extends to the valve body and is connected to the operating shaft; a flow prevention device coupled to a lower portion of the valve stem to maintain airtightness while preventing the valve stem from flowing during operation; bellows connected by mounting upper and lower bellows flanges on the upper and lower sides of the valve stem; a jacket installed to prevent heat conduction by maintaining a vacuum outside the valve body and the bonnet; It is configured to include a plug coupled to the lower end of the valve stem to open and close a flow path formed in the valve body;
A connection pipe body integrally formed on the upper part of the plug body having a hemispherical plug head at the lower end to select the flow of cryogenic fluid through direct connection and separation with the operating surface of the flow path formed inside the valve body and protruding; The connecting protrusion formed at the lower end of the valve stem is coupled with the connecting tube body so that the plug moves up and down by the valve stem, and when there is a reverse flow of cryogenic fluid through the outlet, the pressure of the cryogenic fluid flowing backwards against the connecting protrusion. It is characterized by having the function of blocking the passage by lowering the connecting tube.

Description

Cryogenic valve with check valve function {CRYOGENIC VALVE WITH CHECK VALVE FUNCTION}

The present invention relates to a cryogenic valve having a check valve function, and more particularly, it also functions as a check valve to prevent or block the reverse flow of cryogenic fluid, thereby minimizing installation space while providing ease of installation and maintenance of the valve. It relates to the provision of an improved cryogenic valve.

Cryogenic valves are mainly used in piping systems used for storage and transportation of cryogenic fluids such as liquefied gases such as LNG, LPG, LN ₂ , LH ₂ , etc., and have a long bonnet on the top of the body through which cryogenic fluids are physically distributed. am.

Various types of cryogenic valves as described above have been developed and used in the past, and the configuration of the prior art through patent documents for representative examples is as follows,

In Patent Document 1, a first flow path and a second flow path are formed inside, and a partition portion is formed to divide the first flow path and the second flow path therein, but a fluid passage hole is formed, and an upper portion is opened at the upper part of the partition portion. a valve body in which a space for moving the valve body is formed;

a valve bonnet having a female screw portion for a bonnet formed in the center and coupled to an upper portion of the valve body to close an upper portion of the valve body moving space;

an extension pipe having a lower end coupled to an upper portion of the valve bonnet and extending upward;

An extension portion disposed along the inside of the extension pipe and having a smaller diameter than the inner diameter of the extension pipe, and an extension portion formed directly below the extension portion, the outer diameter of a screw thread being smaller than or equal to the diameter of the extension portion, and the female screw portion for the bonnet. A first male threaded portion screwed with, a snap ring mounting groove formed directly below the first male threaded portion, and a valve body coupling portion having a diameter smaller than or equal to the inner diameter of the thread of the first male threaded portion, and the extension A valve stem having an airtight mounting portion formed directly above the portion and having a diameter smaller than or equal to the diameter of the extension portion, and a handle coupling portion formed on the top of the airtight mounting portion and having a cross section smaller than that of the airtight mounting portion;

an airtight means comprising an airtight member provided between the airtight member mounting portion of the valve stem and the inner circumferential surface of the upper end of the extension pipe;

a handle coupled to the handle coupling part of the valve stem;

It comprises a valve body coupled to the valve body coupling part of the valve stem to open and close the fluid passage hole,

The valve body includes a snap ring mounted in the snap ring mounting groove, an auxiliary mounting hole fixed to the valve body coupling part at an upper portion of the snap ring and having an auxiliary male screw portion formed at the lower portion of the outer circumferential surface and a polygonal flange portion formed at the upper portion of the outer circumferential surface; A valve seat is provided at the bottom, and a female thread forming portion is formed at the top to form a female thread portion screwed with the auxiliary male thread portion of the auxiliary mounting hole. It is characterized in that it comprises a valve disc on which anti-rotation protrusions are formed to prevent rotation of the disc.

In Patent Document 2, a flow path is formed inside the lower valve body, a vertical bonnet is formed on the upper portion of the valve body, and a stem having a disk for opening and closing the flow path is formed inside the valve body and the bonnet, In the cryogenic valve having a structure in which a handle for rotating the stem is connected to the top of the stem extending vertically from the top of the bonnet,

A cylindrical flange connected to the top of the bonnet is formed, and a packing hole having a larger inner diameter than the inner diameter through which the stem passes is formed at a predetermined length inside the center of the top of the bonnet, and the packing is accommodated in the packing hole. And while pressing the upper part of the packing, a pressing means composed of a lower pressing part and an upper support part that are internal to the packing hole is formed, and a first through hole is formed that penetrates from the lower part of the pressing part to the upper part of the support part and internally inserts the stem. It is coupled to the flange of the bonnet as a fastening means in the first fastening holes formed on both sides of the upper portion of the support,

It is located between the flange of the bonnet and the handle, and the second through hole is formed in the center to insert the stem through the horizontal plate-type gap support plate having second fastening holes formed on both sides and the second fastening hole of the gap support plate. A support means coupled to the flange of the bonnet is provided as a fastening means,

A semi-spherical anti-condensation part having a plurality of openings penetrating inside the upper outer circumferential surface is formed in a cylindrical shape while being connected to the lower end of the bonnet,

Located at the lower part of the anti-condensation part, based on the stepped part protruding in a circumferential shape at the center of the outer circumferential surface, the upper outer circumferential surface and the lower outer circumferential surface are sealed with a threaded fastening part and a plurality of first through holes penetrated through the upper surface and the center of the upper surface while sealing the inner center. A socket portion composed of a blocking plate having a third through hole through which the stem passes is provided,

A casing is provided between the socket part and the valve body, the upper part is coupled to the lower fastening part of the socket part, and the lower part is coupled to the valve body to form an internal space,

A cylindrical first heat transfer part accommodated in the space of the casing and having a fourth through hole at the center for the stem to pass through, a vertical first connecting pin connected to the outer circumferential surface of the first heat transfer part and protruding in all directions, and the first A heat transfer member composed of a cylindrical second heat transfer part having an end portion of the connection pin connected to the inner circumferential surface and surrounding the first connection pin on all sides, and a plurality of vertical second connection pins connected to the outer circumferential surface of the second heat transfer part and radially protruding. It is characterized by being provided.

Utility model registration No. 20 - 0478984 - 0000 Patent Registration No. 10 - 1736365 - 0000

doesn't exist.

The cryogenic valve to which the prior art is applied is installed in the middle of the cryogenic fluid line to control the flow of the cryogenic fluid, and performs a function of completely blocking the flow of the cryogenic fluid or controlling the flow rate. A check valve is installed to prevent reverse flow of cryogenic fluid.

Although there may be slight differences in the configuration and shape of the cryogenic valve as described above, it has a generally similar configuration, prevents the cryogenic fluid from vaporizing by external heat transfer, and bonnet and handle parts by heat conduction of the cryogenic fluid. It is a configuration to devise an insulation means to block the occurrence of frost.

In addition to this, a check valve is further installed between the cryogenic valve and the cryogenic valve or between the cryogenic valve and the connection part of the fluid line to limit the reverse movement of the cryogenic fluid.

In this way, if a check valve needs to be installed in addition to the cryogenic valve, there is no difficulty in installing it if there is room in the space to be installed. Disadvantages arise that a separate cost is required.

It takes time and money to install more check valves, but after installing the check valves, the conduction of external air temperature prevents the fluid from vaporizing, and the cryogenic fluid is conducted to the bonnet and handle of the check valve, resulting in frost formation. Since it is necessary to devise an insulation means to prevent the operation from being disturbed, it is not free from the problem of excessive cost.

If you want to devise insulation means for cryogenic valves and check valves, you need to install a vacuum on the outside of the body and bonnet to maintain a vacuum. Since the structure and construction are complicated, such as preventing

Accordingly, in the present invention, as invented to solve the above problems, the inlet 101, the outlet 102, and the valve body 105 formed with the flow path 103;

A long bonnet 106 connected to the upper part of the valve body 105, a gland 108 maintained with a handle 107 on the upper part of the bonnet 106, and connected to the handle 107 an operating shaft 109 protruding downward;

a valve stem 110 whose lower end extends to the valve body 105 and is connected to the operating shaft 109;

A flow prevention device 111 coupled to the lower side of the valve stem 110 to maintain airtightness while preventing the valve stem 110 from flowing during operation;

a bellows 115 connecting upper and lower bellows flanges 112 and 113 to the upper and lower sides of the valve stem 110;

a jacket 116 mounted to prevent heat conduction by maintaining a vacuum outside the valve body 105 and the bonnet 106;

It is configured to include a plug 120 coupled to the lower end of the valve stem 110 to open and close the flow path 103 formed in the valve body 105;

A plug body 123 having a hemispherical plug head 122 at its lower end for selecting the flow of cryogenic fluid through direct connection and separation with the operating surface 121 of the flow path 103 formed inside the valve body 105 A connection tube body 125 integrally formed on the upper part and protruding;

The connection protrusion 126 formed at the lower end of the valve stem 110 is coupled to the connection tube 125 so that the plug 120 rises and falls by the valve stem 110 while the cryogenic fluid flows through the outlet 102. Characterized in that, when there is a reverse flow, the connection pipe body 125 descends with respect to the connection protrusion 126 by the pressure of the cryogenic fluid flowing backward to block the flow path 103;

In the forward direction of the cryogenic fluid, the fluid can be supplied by the rising operation of the plug, and in the case of reverse flow of the cryogenic fluid at the outlet, the pressure of the backward flowing cryogenic fluid lowers the plug to block the flow path to prevent reverse flow. Since there is no need to install check valves, it is possible to achieve the purpose of reducing costs and time for installation and maintenance.

The present invention improves the structure of the cryogenic valve so that the plug located inside the body and operated up and down by the valve stem can also function as a check valve, thereby eliminating the inconvenience of installing a separate check valve, thereby reducing installation cost and time It has the effect of providing ease of maintenance while reducing

In the present invention, the plug of the cryogenic valve rises due to the valve stem and fluid pressure during forward flow so as not to interfere with the fluid flow, and decreases due to fluid pressure during reverse flow to fundamentally block and check the reverse flow of cryogenic fluid. By functioning as a valve, it has the effect of improving the quality and durability of the cryogenic valve.

The present invention improves only the structural relationship between the valve stem and the plug to enable the flow of cryogenic fluid in the forward direction while blocking the movement of cryogenic fluid in the reverse direction, thereby minimizing structural changes in the cryogenic valve and functioning of the valve and check valve. It has an excellent effect of greatly reducing the cost and time of manufacturing, installation and maintenance of cryogenic valves.

1 is an external perspective view showing a cryogenic valve having a check valve function to which the technology of the present invention is applied;
2 is a broken perspective view showing a cryogenic valve having a check valve function to which the technique of the present invention is applied;
3 is a cross-sectional view showing a cryogenic valve having a check valve function to which the technology of the present invention is applied.
4 is an exploded perspective view of a plug portion of a cryogenic valve having a check valve function to which the technology of the present invention is applied;
5 is a broken perspective view of a plug portion of a cryogenic valve having a check valve function to which the technology of the present invention is applied;
6 is a cross-sectional view of a plug portion of a cryogenic valve having a check valve function to which the technique of the present invention is applied.
7 is a forward fluid flow operation state diagram of a cryogenic valve having a check valve function to which the technology of the present invention is applied.
8 is a diagram illustrating a forward flow blocking state of a cryogenic valve having a check valve function to which the technique of the present invention is applied;

Hereinafter, a preferred configuration and operation of the present invention for achieving the above object will be described with reference to the accompanying drawings.

1 is an external perspective view showing a cryogenic valve having a check valve function to which the technology of the present invention is applied, FIG. 2 is a broken perspective view showing a cryogenic valve having a check valve function to which the technology of the present invention is applied, and FIG. 4 is an exploded perspective view of a plug part of a cryogenic valve having a check valve function to which the technology of the present invention is applied, and FIG. 5 is a check valve to which the technology of the present invention is applied. A broken perspective view of a plug portion of a cryogenic valve having a valve function, Figure 6 is a cross-sectional view of a plug portion of a cryogenic valve having a check valve function to which the technology of the present invention is applied, Figure 7 is a check valve to which the technology of the present invention is applied A forward fluid flow operating state diagram of a cryogenic valve having a function, and FIG. 8 is a forward fluid flow blocking state diagram of a cryogenic valve having a check valve function to which the technology of the present invention is applied.

In a typical cryogenic valve 100, an inlet 101 into which cryogenic fluid can flow is formed on one side, an outlet 102 is formed on the opposite side of the inlet 101, and the inlet 101 and the outlet 102 are formed. ) A valve body 105 forming a flow path 103 is provided between them.

A long bonnet 106 is connected to the top of the valve body 105 to reduce the temperature conduction of the cryogenic fluid, and the top of the bonnet 106 is maintained by a gland 108 having a handle 107. do.

An operating shaft 109 protrudes downward from the handle 107 and is positioned at the center of the bonnet 106, and the lower end of the operating shaft 109 is a valve stem 110 whose lower end extends to the valve body 105. Connected to the top, the operation shaft 109 rises and falls by rotation, and the valve stem 110 rises and falls without rotation.

A flow prevention device 111 made of Teflon is coupled to the lower part of the valve stem 110 to prevent the valve stem 110 from flowing during operation and to maintain airtightness, and the upper and lower parts of the valve stem 110 The upper and lower bellows flanges 112 and 113 are mounted on the lower side to connect the bellows 115.

A jacket 116 is mounted on the outside of the valve body 105 and the bonnet 106 to maintain a vacuum to prevent heat conduction, and at the lower end of the valve stem 110, a flow path formed in the valve body 105 ( The plug 120 for opening and closing the 103 is coupled.

In the present invention, by improving the valve stem 110 and the plug 120 to serve as a check valve, the ease of installation and maintenance of the cryogenic valve 100 is eliminated while eliminating the hassle of separately providing and installing the check valve. It is characterized in that it can provide.

Cylindrical plug body 123 having a hemispherical plug head 122 at the bottom that selects the flow of cryogenic fluid through direct connection and separation with the operating surface 121 of the flow path 103 formed inside the valve body 105 ) is provided.

A connection tube 125 is integrally formed on the upper part of the plug body 123 to protrude, and a connection protrusion 126 formed at the lower end of the valve stem 110 is coupled to the connection tube 125.

The connection tube body 125 and the connection protrusion 126 are combined so that they are in a form capable of maintaining the bonding force using the dimensional difference without fixing with a separate fixing means such as a screw or bond, and the connection tube body 125 The bonding force of the protrusion 126 is greater than the weight of the plug 120 and less than the pressure of the cryogenic fluid flowing backward through the outlet 102, so that the connection tube 125 and the connection protrusion 126 is not separated, and allows the connecting tube 125 to operate downward with respect to the connecting protrusion 126 only by the reverse flow pressure of the cryogenic fluid.

The length L of the connecting tube body 125 and the connecting protrusion 126 is longer than the maximum stroke at which the plug 100 opens and closes the flow path 103, so that the connecting tube body 125 is connected to the connecting protrusion 126 during operation. ) would be desirable to prevent it from escaping into a malfunctioning or inoperable condition.

In addition, the upper side of the plug body 123 constituting the flag 120 is positioned at an intermediate position between the outlet 102 and the flow path 103 so that the cryogenic fluid flowing backward through the outlet 102 is passed through the plug body 123. It is preferable to be able to block the passage 103 by rapidly descending upon receiving the transmission.

An operating state of the cryogenic valve 100 to which the technology of the present invention is applied as described above is as follows.

After the cryogenic valve 100 is installed in the line where the cryogenic fluid is to be circulated, if the cryogenic fluid is to be circulated, the valve stem 110 is raised through the operating shaft 109 by manipulating the handle 107. The plug 120 connected to the stem 110 and connected to the operating surface 121 of the flow path 103 formed inside the valve body 105 is raised.

Then, since the connection pipe body 125 formed to protrude from the top of the plug body 123 and the connection protrusion 126 formed at the lower end of the valve stem 110 are coupled to each other, the plug body moves as the valve stem 110 rises. Since 123 also rises together, it is possible for the cryogenic fluid to move to a desired position through the inlet 101, the passage 103, and the outlet 102.

In addition, in spite of the need to continuously supply the cryogenic fluid to the desired location, if the reverse flow of the cryogenic fluid occurs at the outlet 102, the plug 120 serves as a check valve to maintain the cryogenic temperature at the outlet 102. It is possible to prevent fluid from flowing backward into the flow path 103 and the inlet 101 .

This is because the connecting tube body 125 and the connecting protrusion 126 are not fixed with a separate fixing means such as a screw or bond, and the coupling force can be maintained using the dimensional difference, so the valve stem 110 usually rises. Alternatively, during the descending operation, the plug 120 rises and descends together with the valve stem 110 .

In addition, when there is a reverse flow of cryogenic fluid at the outlet 102, the reverse flow of cryogenic fluid fills the outlet 102 and the upper portion of the flow path 103, and the pressure of the cryogenic fluid is applied to the plug 120 at the top of the plug. It acts as a force to lower the 120, and when this force becomes greater than the pressure of the fluid supplied through the inlet 101, the plug 120 descends to block the operating surface 121 of the flow path 103. This will prevent backflow of the cryogenic fluid.

This is the lifting operation process for opening and closing the passage 103 by making the coupling force between the connecting tube body 125 and the connecting protrusion 126 greater than the weight of the plug 120 and less than the pressure of the cryogenic fluid flowing backward through the outlet 102. This is possible because the connecting tube body 125 and the connecting protrusion 126 are not separated and are coupled so that the connecting tube body 125 can descend with respect to the connecting protrusion 126 only by the reverse flow pressure of the cryogenic fluid.

For this reason, in a normal state, the cryogenic fluid introduced through the inlet 101 passes through the space between the raised plug 120 and the flow path 103, and supplies the cryogenic fluid to the desired location through the outlet 102. it will be possible

When the cryogenic fluid in the direction of the outlet 102 flows backward even though the operation surface 121 of the flow path 103 is not blocked by the downward operation of the plug 120, the plug 120 is moved by the pressure of the backward flowing cryogenic fluid. Since the flow path 103 is blocked by the descending operation, it is possible to perform the function of blocking the reverse flow even though the check valve is not separately installed.

As described above, in the present invention, the fluid can be supplied by the upward operation of the plug in the forward direction of the cryogenic fluid, and when the cryogenic fluid flows backward at the outlet position, the plug is lowered by the pressure of the cryogenic fluid flowing backward to block the flow path to prevent reverse flow. By preventing it, it is not necessary to install a separate check valve, so it has the advantage of reducing cost and time for installation and maintenance.

100; cryogenic valve
103; Euro
105; valve body
106; bonnet
107; handle
110; valve stem
111; flow prevention device
112; Top Bellows Flange
113; Lower Bellows Flange
115; bellows
120; plug
122; plug head
123; plug body
125; connector body
126; connection protrusion

Claims (4)

a valve body 105 having an inlet 101, an outlet 102, and a flow path 103;
A long bonnet 106 connected to the upper part of the valve body 105, a gland 108 maintained with a handle 107 on the upper part of the bonnet 106, and connected to the handle 107 an operating shaft 109 protruding downward;
a valve stem 110 whose lower end extends to the valve body 105 and is connected to the operating shaft 109;
A flow prevention device 111 coupled to the lower side of the valve stem 110 to maintain airtightness while preventing the valve stem 110 from flowing during operation;
a bellows 115 connecting upper and lower bellows flanges 112 and 113 to the upper and lower sides of the valve stem 110;
a jacket 116 mounted to prevent heat conduction by maintaining a vacuum outside the valve body 105 and the bonnet 106;
It is configured to include a plug 120 coupled to the lower end of the valve stem 110 to open and close the flow path 103 formed in the valve body 105;
A plug body 123 having a hemispherical plug head 122 at its lower end for selecting the flow of cryogenic fluid through direct connection and separation with the operating surface 121 of the flow path 103 formed inside the valve body 105 A connecting tube body 125 integrally formed on the upper part and protruding;
The connection protrusion 126 formed at the lower end of the valve stem 110 is coupled to the connection tube 125 so that the plug 120 rises and falls by the valve stem 110 while the cryogenic fluid flows through the outlet 102. A cryogenic valve having a check valve function, characterized in that when there is a reverse flow, the connection pipe body 125 descends with respect to the connection protrusion 126 by the pressure of the cryogenic fluid flowing backward to block the flow path 103. According to claim 1;
The connecting tube body 125 and the connecting protrusion 126 maintain bonding force using a difference in size;
A cryogenic valve having a check valve function, characterized in that the coupling force between the connecting tube body 125 and the connecting protrusion 126 is greater than the weight of the plug 120 and smaller than the pressure of the cryogenic fluid flowing back through the outlet 102 . According to claim 1;
The length L of the connecting tube body 125 and the connecting protrusion 126 is longer than the maximum stroke at which the plug 100 opens and closes the flow path 103, so that the connecting tube body 125 is connected to the connecting protrusion 126 during operation. ) A cryogenic valve having a check valve function, characterized in that it does not escape. According to claim 1;
The upper side of the plug body 123 is located at an intermediate position between the outlet 102 and the flow path 103 so that the plug body 123 receives the cryogenic fluid flowing backward and quickly descends to block the flow path 103 A cryogenic valve having a check valve function, characterized in that.

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