KR100454723B1 - Cryogenic valve - Google Patents

Abstract

Cryogenic valve of the present invention, the hole is formed ball; A body for receiving the ball, one end coupled to a handle and the other end coupled to an upper portion of the ball; And a bonnet surrounding the outer circumferential surface of the stem and fastened to an upper portion of the body to prevent the fluid from leaking from the ball, the body and the stem, comprising: a spring for buffering the pressure of the fluid; First stop ring having a cavity for accommodating the spring, one side is in contact with one end of the spring and the other side is in contact with the inner surface of the body and the first seat gasket partly inserted into one recess of the first stop ring And a shock absorbing member having a first seat ring in contact with the other end of the spring and partially inserted into the other concave portion facing the one concave portion of the first stop ring to contact the ball. And a second seat ring in contact with an outer surface of the ball, a second seat dog gasket in contact with an inner side surface of the body, and concave portions at both ends in contact with opposite surfaces of the second seat ring and the second seat gasket. A second stop ring for seating the second seat ring and the second seat gasket, respectively, and a third seat gasket inserted between the face of the second stop ring and the face of the second seat ring opposite the contact surface with the ball. It characterized by having a shield member having a.

Description

Cryogenic valve

The present invention relates to a cryogenic valve, and more particularly, to a cryogenic valve capable of opening and closing a valve with a small torque when opening and closing the valve as well as maintaining airtightness at cryogenic temperatures.

As is well known, the demand for valves for cryogenic fluids such as liquid nitrogen, liquid oxygen, and natural liquefied gas (LNG) is increasing day by day.

Because these cryogenic fluids are very low in temperature, the materials and constructions used for the valves are different from those used for normal room temperature.

In particular, the material of the cryogenic valve can maintain the airtightness of the valve if the deformation does not occur well even at cryogenic temperatures.

Thus, PCTFE is used as a shielding material as a material that is hardly deformed in a cryogenic state.

We will describe a conventional cryogenic valve using such a material.

FIG. 1 is a cross-sectional view of a conventional cryogenic valve using a shield material of PCTFE, and FIG. 2 is an enlarged view of portion A of FIG. 1.

The conventional cryogenic valve, as shown in FIG. 1, has a handle 807 coupled to the body 802, stem 803, through which fluid can pass from the first passage 814 to the second passage 875. Ball 801 having a cylindrical cavity capable of opening and closing the fluid by the fluid, a bonnet 804 covering the stem 803 to which the ball 801 is connected, a support plate 812 for supporting the handle 807, A packing member for preventing fluid from leaking from the upper portion of the bolt 809 for fastening the bonnet 804 and the support plate 812 via the flange portion 808 and the stem 803 in close contact with the bonnet 804 ( 811 and a gland 810 in close contact therewith.

Such conventional cryogenic valves have a PCTFE 805 between the body 802 and the ball 801 to prevent fluid from leaking between the body 802 and the ball 801 when the ball 801 is in the closed state. ) And the graphite 806 is characterized in that the shield member is inserted.

As described above, the PCTFE 805 is used as a shield member between the body 802 and the ball 801 because deformation does not easily occur at an extremely low temperature, and the first passage 814 or the second passage 815 The graphite 806 is bonded to the PCTFE 805 which can buffer the pressure exerted on the ball 801 from the fluid.

However, such a shield member has a high pressure on the ball 801 from the fluid of the first passage 814 or the second passage 815, so that between the PCTFE 805 and the body 802 or the graphite 806 and The friction between the balls 801 is quite large.

Accordingly, the PCTFE 805, the body 802, the graphite 806, or the ball 801 between the PCTFE 805 and the body 802 or between the graphite 806 and the ball 801 as the number of opening and closing of the valve increases. ), And as a result, fluid leaks between the body 802 and the ball 801.

In addition, as discussed above, the friction between the PCTFE 805 and the body 802 or between the graphite 806 and the ball 801 is so great that a great deal of torque must be given to the handle 807 upon opening and closing the valve. .

In order to provide such a large torque, the radius of the handle 807 must be increased, thereby increasing the space occupied by the valve.

Accordingly, an object of the present invention is to reduce the friction force between the body of the valve and the shield member during the rotation of the ball for opening and closing the valve to facilitate the rotation of the valve.

In addition, another object of the present invention is to improve the sealing force between the ball and the body of the valve using the pressure of the fluid.

In addition, another object of the present invention is to facilitate the detachment of the ball using a tapered method.

Other objects of the present invention will become apparent from the following description.

1 is a cross-sectional view of a conventional cryogenic valve,

2 is an enlarged view illustrating an enlarged portion A of FIG. 1;

3 is a view showing the external appearance of the cryogenic valve according to the embodiment of the present invention;

4 is a cross-sectional view of the cryogenic valve according to the embodiment of the present invention;

5 is a cross-sectional view taken along the line C-C of FIG.

6 is an enlarged view of a portion B of FIG. 4.

* Description of the symbols for the main parts of the drawings *

1 Body 2 Shock Absorber

3: shield member 4: stem

5: gasket 6: bonnet

7: Bonnet Bolt 8: Bonnet Nut

9: Packing Guide 10: Packing

11: gland 12: gland flange

13: Gland bolt 14: Gland nut

15: Handle 16: Handle Nut

17: spring 18: cavity

19: support ring 20: nut

27 ball 30 connection pipe

41: bushing 42: bushing washer

121: fastening hole 122: flange

131: facing surface 132: facing surface

201: second seat gasket 202: first seat ring

203: second seat ring 204: first seat gasket

205: third seat gasket 206: first stop ring

207: second stop ring 271: hole

272: insertion portion 273: surface

274: face 301: fastening bolt

302: nut 303: flange

401: stem guide 402: sleeve washer

403: Ball Guide 701: Spring Washer

Cryogenic valve according to an aspect of the present invention, the hole is formed ball; A body connected to the connection pipe and configured to receive the ball; A stem having one end coupled to the handle and the other end coupled to the top of the ball; And a bonnet coupled to an upper portion of the body to surround the outer circumferential surface of the stem to prevent leakage of the fluid from the ball, the body and the stem, the spring for buffering the pressure of the fluid; First stop ring having a cavity for receiving the spring, one side is in contact with one end of the spring and the other side is in contact with the inner side of the body and the first seat gasket is a part inserted into one recess of the first stop ring And a shock absorbing member having a first seat ring in contact with the other end of the spring and partially inserted into the other concave portion facing the one concave portion of the first stop ring to contact the ball. And

A second seat ring in contact with an outer surface of the ball, a second seat gasket in contact with an inner side surface of the body, and concave portions at both ends in contact with respective opposite surfaces of the second seat ring and the second seat gasket. A second stop ring for seating the second seat ring and the second seat gasket, respectively, and a third seat gasket inserted between the face of the second stop ring opposite the contact surface with the ball and the face of the second seat ring. It has a shield member having a,

The buffer member is positioned on a first contact surface of the ball and the body, and the shield member is positioned on a second contact surface of the ball and the body.

In this case, it is preferable that the inner surfaces of the body for receiving the ball and the outer surfaces of the ball at both ends of the hole have a tapered shape.

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

Figure 3 is a view showing the appearance of the cryogenic valve according to an embodiment of the present invention, Figure 4 is a cross-sectional view of the cryogenic valve according to an embodiment of the present invention.

5 is a cross-sectional view taken along line C-C of FIG. 3, and FIG. 6 is an enlarged view of a portion B of FIG. 4.

As shown in FIG. 4, the flange portion 122 coupled to the flange portion 303 of the connection pipe 30 and fastened and fastened by a plurality of fastening bolts 301 and nuts 302 fitted into the fastening holes 121 is fixed. A body (1) having a ball (27) of the valve having a valve capable of shielding the flow of fluid; It has a hole 271 that is received in the inner side of the body (1) and through which fluid can pass, and has an insert (272) at the top through which the lower projection in the stem (4) can be inserted, and the lower part with a bushing ( A ball 27 inserted into a groove formed in the lower inner side of the body 1 through the 41 and the bushing washer 42; And the lower side of the ball 27 is inserted through the ball guide 403 in contact with the outside of the insertion portion 272 of the ball 27 and the stem guide 401 in contact with the outside of the ball guide 403. The body (b) by the bonnet bolt 7 and the spring washer 701 / bonnet nut 8 through the fastening hole formed in the outer periphery of the lower part and the upper part of the body 1 in contact with the outside of the part 272 1) and a bonnet 6 to be fastened, and between the one side of the outside of the ball 27 and the one side of the inner side of the body 1 to seal between the one inner side of the body 7 and the outer one side of the ball 27. In addition, it is further provided with a shield member (3) for sealing between the buffer member (2) to facilitate the rotation of the ball 27 and the other side of the inner side of the body (1) and the outer other surface of the ball (27).

Further, the gasket 5 is inserted between the lower end of the bonnet 6 in contact with the body 1 and the upper end of the body 1 in contact with the lower end of the bonnet 6, whereby the lower end of the bonnet 6 and the body 1. Be kept confidential between the top of the.

In addition, a sleeve washer 402 is installed between the upper end of the stem guide 401 and the bonnet 6.

On the other hand, the configuration of the bonnet 6 and the upper portion of the stem 4 is configured similarly to the configuration of a general cryogenic valve.

As shown in FIG. 4, the packing guide 9, the packing 10, and the gland (from the lower part are formed from the lower part in order to provide a seal between the upper inner side of the bonnet 6 and the outer circumferential surface of the stem 4). 11) is inserted, the gland bolt 13 and the gland nut passing through the fastening hole of the gland flange 12 surrounding the outer peripheral surface of the gland 11 and the fastening hole of the flange at the upper portion of the bonnet 6 By means of 14 the bonnet 6 is fastened to the gland flange 12 of the handle 15 via a support ring 19 for supporting the stem 4.

The upper end of the stem 4 is coupled with the handle 15 by being fastened with a nut 20 in a state of passing through a fastening hole in the center portion of the handle 15.

As shown in FIG. 6, the shock absorbing member 2 has a first stop ring 206 having a cavity 18 capable of receiving a spring 17, a spring received in a cavity 18 of the first stop ring 206. (17), the first sheet gasket 204, which is in contact with one end of the spring 17 and is partially inserted into one recess of the first stop ring 206, and the other end of the spring 17, and is in contact with the first stop ring. A first seat ring 202 has a portion inserted into the other concave portion of 206.

The surface of the first sheet gasket 204 opposite to the surface in contact with the spring 17 is in contact with one surface of the inner side of the body 1.

The surface of the first seat ring 202 opposite to the surface in contact with the spring 17 is in contact with one surface outside the ball 27.

In the constituent material of the shock absorbing member 2, the first seat ring 202 and the first seat gasket 204 are made of PCTFE which is less deformable at cryogenic temperatures, and the first stop ring 206 is made of, for example, SUS316. Is made of stainless steel.

On the other hand, as shown in Figure 6, the shield member 3 is the second seat ring 203 in contact with the outer surface of the ball 27, the second seat gasket 201 in contact with one surface of the inner side of the body (1), And a second stop ring contacting opposite surfaces of the second seat ring 203 and the second seat gasket 201 to seat the second seat ring 203 and the second seat gasket 201 at recesses, respectively. 207, a third sheet gasket 205 inserted between the surface of the second stop ring 207 and the surface of the second seat ring 203 opposite the contact surface with the ball 27.

Here, the second sheet gasket 201 is a laminate of PCTFE and graphite.

In the constituent material of the shield member 3, the second seat ring 203 is made of PCTFE, the third seat gasket 205 is made of graphite, and the second stop ring 207 is made of, for example, SUS316. Is made of stainless steel.

Also, the distance between the faces 273 and 274 at both ends of the hole 271 in the ball 27 and the opposing faces 131 and 132 on the inner side of the body 1 containing the ball 27. The surfaces 273 and 274 and the opposing surfaces 131 and 132 are inclined so that the distance between them becomes smaller from the top to the bottom of the ball 27.

That is, the inner side surfaces 131 and 132 of the body 1 which accommodates the ball 27 and the outer surfaces 273 and 274 of the ball 27 at both ends of the hole 271 have a tapered shape.

Hereinafter, the operation and effects of the cryogenic ball according to the embodiment of the present invention.

When opening the cryogenic valve according to the embodiment of the present invention, when the handle 15 is rotated, the lower end of the stem 4 is inserted into the insertion portion 272 to rotate the ball 27, the fastened ball 27 The axis of the hole 271 penetrating the center of the () is arranged in the same direction as the axis of the body (1) through which the fluid passes.

On the contrary, when the valve is closed, the handle 1 connected to the ball 27 via the stem 4 is further rotated so that the shaft 1 of the hole 271 in the ball 27 passes through the body 1. It is made perpendicular to the axis of.

As described above, the spring 17 is inserted into the cavity 18 of the first stop ring 206 of the shock absorbing member 2 which is in contact with one surface of the outside of the ball 27, so that fluid is transferred to the ball 27. The exerting pressure is buffered and reduced by the tension of the spring 17.

Therefore, when the ball 27 is rotated to open and close the valve, the pressure applied to the ball 27 is reduced, so that the frictional force between the buffer member 2 and the ball 27 and the body 1 is reduced. A small torque can be applied to the handle 15 connected to the ball 27 via the stem 4 to easily open and close the valve.

In this way, the valve can be easily opened and closed with a small torque, so that the radius of the handle 15 can be reduced by that much, thereby reducing the space occupied by the valve.

On the other hand, when the valve is closed, even if the fluid leaks from the part where the buffer member 2 and the inner side of the body 1 are in contact, or the part where the buffer member 2 and the outer surface of the ball 27 are in contact with each other, Due to the pressure applied to the ball 27, the outer surface of the ball 27 applies pressure to the shield member 3 in contact with the outer surface of the ball 27.

Due to the pressure applied in this way, the outer surface of the ball 27 applies pressure to the second seat ring 203 on one side of the second stop ring 207, so that the ball 27 and the second seat ring ( 203) is sealed.

In addition, since the pressure caused by the fluid is transmitted to the second stop ring 207 via the second seat ring 203, the third seat gasket between the second seat ring 203 and the second stop ring 207. 205 seals between the second seat ring 203 and the second stop ring 207.

Further, at this time, the pressure caused by the fluid continues to pass through the second seat gasket 201 between the inner surface of the body 1 and the opposite surface of the second stop ring 207 opposite thereto. It is also passed to the side.

As a result, the inner side of the body 1 and the second stop ring 207 are also closed.

Therefore, it is possible to prevent the fluid from leaking from one connecting pipe to the other connecting pipe when the valve is closed.

In addition, the inner side surfaces 131 and 132 of the body 1 which accommodates the ball 27 and the outer surfaces 273 and 274 of the ball 27 at both ends of the hole 271 have a tapered shape. When the ball 27 is to be replaced due to the wear of the 27, the bonnet bolt 7 and the bonnet nut 8 which are fastened to the bonnet 6 and the body 1 are released, and the ball 27 and the buffer are released. After removing the member 2, the shield member 3, and the bonnet 6 except the body 1, the stem 4, and the like, the shield member 3 and the balls 27 in close contact with them are held together. Easily pulled out and put back.

As such, since the inner side surfaces 131 and 132 of the body 1 of the cryogenic valve 1 and the outer side surfaces 273 and 274 of the ball 27 have a tapered shape, the replacement of the ball 27 is performed. It is easy.

As described above, according to the cryogenic valve according to the embodiment of the present invention, by maintaining the airtight of the shield member by the pressure of the fluid, the fluid is prevented from leaking from one connecting pipe to the other connecting pipe when the valve is closed. can do.

In addition, in the first stop ring of the first shield member, the spring buffers the pressure of the fluid, thereby reducing the torque at the time of opening and closing the valve, thereby reducing the radius of the handle, thereby reducing the space of the valve. have.

In addition, the outer surfaces of the ball and the inner sides of the body that accommodates the ball have a tapered shape, thereby facilitating replacement of the ball.

Claims (9)

A ball 27 in which a hole 271 is formed; A body (1) connected to the connection pipe (37) for receiving the ball (27); A stem 4 having one end coupled to the handle 15 and the other end coupled to the upper portion of the ball 27; Bonnet 6 fastened to the upper part of the body 1 surrounding the outer circumferential surface of the stem 4 to prevent leakage of fluid from the ball 27, the body 1 and the stem 4 In the cryogenic valve comprising: A first stop ring 206 having a spring 17 for damping the pressure of the fluid, a cavity 18 for receiving the spring 17, one side of which is in contact with one end of the spring 17 and the other side of which is a body A first seat gasket 204 which is in contact with the inner side of (1) and a part of which is inserted into one concave portion of the first stop ring 206, and the other end of the spring 17, and the first stop ring A shock absorbing member (2) having a first seat ring (202) inserted into the other concave portion opposite the one concave portion of the (206) to be in contact with the ball (27); And A second seat ring 203 in contact with an outer surface of the ball 27, a second seat gasket 201 in contact with an inner side surface of the body 1, the second seat ring 203 and the second seat A second stop ring 207 for seating the second seat ring 203 and the second seat gasket 201 at recesses at both ends and in contact with opposite surfaces of the gasket 201, and the ball 27 Shield member (3) having a third seat gasket (205) inserted between the surface of the second stop ring (207) and the surface of the second seat ring (203) opposite the contact surface with The buffer member 2 is positioned on the first contact surface of the ball 27 and the body 1, and the shield member 3 is positioned on the second contact surface of the ball 27 and the body 1. Cryogenic valve, characterized in that. The method of claim 1, Cryogenic valve, characterized in that the first seat ring (202) is made of PCTFE. The method of claim 1, Cryogenic valve, characterized in that the first seat gasket 204 is made of PCTFE. The method of claim 1, Cryogenic valve, characterized in that the first stop ring (206) made of stainless steel. The method of claim 1, The second seat gasket 201 is a cryogenic valve, characterized in that the laminate of PCTFE and graphite. The method of claim 1, Cryogenic valve, characterized in that the second seat ring (203) is made of PCTFE. The method of claim 1, The third seat gasket 205 is a cryogenic valve, characterized in that made of graphite. The method of claim 1, Cryogenic valve, characterized in that the second stop ring (207) made of stainless steel. The method of claim 1, The inner side surfaces 131 and 132 of the body 1 for receiving the ball 27 and the outer surfaces 273 and 274 of the ball 27 at both ends of the hole 271 are tapered. Cryogenic valve.