KR20110024800A - Bellows globe valve - Google Patents

Abstract

PURPOSE: A bellows globe valve, which improves the structure of a stem bed opening and closing and a flow path and a handle, is provided to improve stability and reliability of a valve by improving the sealing ability of a flowing path. CONSTITUTION: A bellows globe valve comprises a body(10), a stem(20), a stem bed(30), a bellows(40), an axis member(50) and a manipulating handle(60). The flow path is formed in the body. The stem can ascend and descend about the body. The stem bed closes the flow path with ascending and descending of stem as opening. The bellows is formed in the outer circumference of the stem. The axis member is screwed in the stem and moves up and down the stem with rotation. The manipulating handle is combined in the axis member.

Description

Bellows globe valve

This technology relates to a bellows globe valve, and more particularly, to a bellows globe valve having an improved structure of a stem provided for opening and closing a handle and a flow path provided for a user's operation.

In general, the globe valve (Globe valve) is a valve in which the inlet and outlet of the valve is connected to the S-shaped flow path, the center line of the inlet and the outlet is collinear.

In addition, the bellows globe valve refers to a valve having improved airtightness by providing bellows inside the globe valve. The bellows globe valve is a fluid having a toxic fluid, a fluid having a constant viscosity, and a high temperature steam, etc., in a steel mill or a chemical factory. Mainly used for piping.

1 is a perspective view of a conventional bellows globe valve, and FIG. 2 is a cross-sectional view of a conventional bellows globe valve.

As shown in FIGS. 1 and 2, the conventional bellows globe valve 500 opens or closes a passage 513 formed in the body 509 as the stem 520 moves up and down within the body 509. It is made of a structure that opens and closes. Flange portions 501 are formed at both sides of the body 509 to be coupled to other flanges, and the flow path 513 connects the inlet 511 and the outlet 512 of the body 509.

The shaft member 550 is screwed to the upper portion of the stem 520, the operation handle 560 for the user's operation is fixed to the upper portion of the shaft member 550. Accordingly, the shaft member 550 is rotated by the rotation of the operation handle 560, and the stem 520 screwed with the shaft member 550 is moved in the vertical direction. The stem bed 530 is fixed to the lower portion of the stem 520 to open and close the flow path 513 as the stem 520 moves up and down. An outer periphery of the stem 520 is formed with a bellows 540 which is airtight, and a bonnet 580 is provided outside the bellows 540.

The conventional bellows globe valve 500 having such a configuration has a structure in which the stem 520 opens and closes the flow path 513 as the operation handle 560 is rotated about 2.5 turns. That is, when the steering wheel 560 is rotated about 2.5 turns clockwise, the stem 520 is lowered and the valve is closed, and when the steering wheel 560 is rotated about 2.5 turns counterclockwise, the stem 520 is raised and the valve Will be opened.

However, the conventional bellows globe valve was not able to confirm whether the valve is open or closed through the appearance state of the operation handle. That is, since the operation handle was formed in a circular shape with a radial handle and the valve was opened and closed through rotation, the user could not identify whether the valve is currently fully open, fully closed, or only partially open.

If the user wants to check the open / closed state of the valve, an additional operation of checking whether the rotation is possible by rotating the operation handle clockwise or counterclockwise has to be performed.

On the other hand, the conventional bellows globe valve has a structure in which the surface facing the stem bed and the body is formed to be in close contact with each other, the problem of inferior airtightness and the stem bed whenever the valve is closed by rotating the handle clockwise There is a problem that is not properly sealed because it is seated in a different position of the body each time.

In order to solve such a conventional problem, the valve is opened and closed according to a predetermined rotation angle of the operation handle and provides a bellows globe valve that can easily identify whether the valve is opened or closed.

In addition, improving the shape of the opposite side of the stem bed and the body provides a bellows globe valve that improves airtightness as the stem bed is seated exactly in the same position on the opposite side of the body at every closure.

The bellows globe valve includes a body having a flow path formed therein, a stem that can be raised and lowered relative to the body, a stem bed that opens or closes the flow path by lifting and lowering the stem, a bellows formed at an outer circumference of the stem, and a screw on the stem. It is coupled to the shaft member for lifting and lowering the stem by the rotation, and the operation handle coupled to the shaft member, the operation handle is formed asymmetrically about the shaft member to enable the external identification of opening and closing of the flow path.

In this case, the pitch of the thread for coupling the shaft member and the stem is preferably formed so that the stem bed opens or closes the flow path as the operation handle is rotated at a predetermined rotation angle.

In addition, it is preferable that the predetermined rotation angle is 180 degrees, and the pitch of the thread connecting the shaft member and the stem is formed to be 4 mm.

Moreover, it is preferable that the cross section of a screw thread becomes trapezoid shape.

In addition, the end of the stem bed is formed to be inclined so that the diameter becomes smaller toward the bottom, the body is preferably formed in the inclined portion corresponding to the end of the stem bed in contact with the end of the stem bed.

Therefore, the bellows globe valve can immediately identify whether the valve is open or closed without further operation, thereby improving operability.

In addition, since the opening and closing airtightness of the flow path is improved, the safety and reliability of the valve can be improved.

Hereinafter, the technical configuration of the bellows globe valve according to the accompanying drawings will be described in detail.

3 is a perspective view of a bellows globe valve according to an embodiment, FIG. 4 is a cross-sectional view of a bellows globe valve according to an embodiment, and FIG. 5 is a cross-sectional view illustrating an operation example of FIG. 4.

3 to 5, the bellows globe valve 1 includes a body 10, a stem 20, a stem bed 30, a bellows 40, a shaft member 50, and an operation. The handle 60 is provided.

The body 10 has a flow path 110 therein. The flow path 110 is formed in an S-shape inside the body 10 and connects the inlet 111 and the outlet 112 of the valve. In this case, the center lines of the inlet 111 and the outlet 112 are located on the same line. Both sides of the body 10 may be formed with a flange portion 101 for coupling with other flanges.

The stem 20 is arranged to be elevated relative to the body 10. That is, an opening is formed in an upper portion of the body 10, and the opening is in communication with the space part 120 and the flow path 110 formed inside the body 10. The stem 20 is connected to the opening of the body 10. The fixing member 210 is fastened to the lower portion of the stem 20, and the fixing member 210 is raised and lowered together with the stem 20.

The stem bed 30 is fastened to the lower portion of the fixing member 210 to open or close the flow path 110 by the lifting and lowering of the stem 20. Stem bed 30 is preferably made of a polytetrafluoroethylene (PTFE) -based fluorine resin having a low coefficient of friction and excellent chemical resistance.

That is, when the stem 20 is moved downward, the stem bed 30 is also moved downward so that the bottom of the stem bed 30 is in close contact with the bottom surface of the space 120 formed inside the body 10. Thus, the flow of fluid from inlet 111 to outlet 112 is blocked. In addition, when the stem 20 is moved upward, the stem bed 30 is also moved upwards so that the bottom of the stem bed 30 is spaced apart from the bottom surface of the space part 120 formed inside the body 10. Thus, the flow of fluid from inlet 111 to outlet 112 proceeds.

The bellows 40 is formed on the outer circumference of the stem 20 to perform a sealing function. That is, the bellows 40 prevents the fluid flowing through the flow path 110 from flowing upward through the fine gaps between the stem 20 and the body 10.

FIG. 6 is an enlarged cross-sectional view of "A" in FIG. 4. As shown in FIG. 6, the shaft member 50 is screwed to the stem 20. A male thread 510 is formed at the lower periphery of the shaft member 50, and a female thread 220 corresponding to the male thread 510 of the shaft member 50 is formed at the upper portion of the stem 20. It is also possible to form a female thread on the shaft member 50 and a male thread on the stem 20.

The operation handle 60 is fastened to the upper portion of the shaft member 50. The operation handle 60 is held by the user's hand, and the shaft member 50 is also integrally rotated together by the rotation of the operation handle 60. The bonnet 80 is coupled to the upper portion of the body 10. The shaft member 50 is rotatably connected to the bonnet 80, and the operation handle 60 is disposed above the bonnet 80 to be integrally rotated together with the shaft member 50.

In particular, the pitch of the male screw thread 510 formed on the shaft member 50 and the female screw thread 220 formed on the stem 20 is such that the stem bed 30 has a flow path 110 as the operation handle 60 is rotated 180 °. ) Is opened or closed. That is, when the operation handle 60 is rotated 180 ° clockwise, the stem 20 is moved downward, so that the stem bed 30 closes the flow path 110. In addition, when the operation handle 60 is rotated 180 degrees counterclockwise, the stem 20 is moved upward, the stem bed 30 opens the flow path (110).

In this case, the pitch of the male screw thread 510 formed in the shaft member 50 and the female screw thread 220 formed in the stem 20 is preferably 4 mm.

In addition, it is preferable that the cross section of the male screw thread 510 formed in the shaft member 50 and the female screw thread 220 formed in the stem 20 has a trapezoidal shape.

Accordingly, the male screw thread 510 and the female screw thread 220 are structurally stable while having a relatively large pitch. That is, the pitch of the threads 510 and 220 for coupling the shaft member 50 and the stem 20 is made relatively large, opening and closing of the valve can be achieved even by 180 ° rotation of the operation handle 60, and the stable screw Threads 510 and 220 are formed in a trapezoidal cross section for coupling.

In addition, the operation handle 60 is preferably formed asymmetrically about the shaft member (50). Therefore, it is easy to externally identify whether the flow path 110 is opened or closed. In addition, since the operation handle 60 is formed asymmetrically, the operation is facilitated by the principle of the lever.

FIG. 7 is an enlarged cross-sectional view of "B" in FIG. 4. As shown in Figure 7, the end of the stem bed 30 is formed to be inclined so that the diameter becomes smaller toward the bottom. In this case, the body 10 is formed to be inclined to correspond to the end portion of the stem bed 30, that is, the bottom surface of the space portion 120 formed in the body 10, that is, contact with the end of the stem bed (30).

That is, the stem bed 30 is inserted into and fixed to the protrusion 221 formed under the fixing member 210, and the inclined surface 301 is formed at the lower end of the stem bed 30. In addition, the body 10 is formed with an inclined surface 121 corresponding to the inclined surface 301 formed on the stem bed 30.

Therefore, when the stem bed 30 descends in the direction of blocking the flow path 110, the inclined surface 301 of the stem bed 301 is brought into and in close contact with the inclined surface 121 of the body 10. Therefore, the airtightness of the valve can be further improved, and the lifting system bed 30 of the stem bed 30 can always be seated in the correct position of the body 10.

The bellows globe valve has been described with reference to the embodiment shown in the drawings so far, but this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope should be defined by the technical spirit of the appended claims.

1 is a perspective view of a conventional bellows globe valve.

2 is a cross-sectional view of a conventional bellows globe valve.

3 is a perspective view of a bellows globe valve according to one embodiment.

4 is a cross-sectional view of the bellows globe valve according to one embodiment.

5 is a cross-sectional view showing an example of the operation of FIG.

6 is an enlarged cross-sectional view of "A" in FIG. 4.

7 is an enlarged cross-sectional view of "B" in FIG. 4.

<Description of the symbols for the main parts of the drawings>

1: Globe Valve 10: Body

20: stem 30: stem bed

40: bellows 50: shaft member

60: operation handle 110: euro

220: female thread 510: male thread

Claims (5)

A body having a flow path formed therein, a stem capable of lifting up and down relative to the body, a stem bed for opening or closing the flow path by lifting up and down the stem, a bellows formed at an outer periphery of the stem, and In the bellows globe valve having a screw member coupled to the lifting and lowering the stem by rotation, and the operation handle coupled to the shaft member, The operation handle is asymmetrically formed around the shaft member, the bellows globe valve can be identified from the outside whether the opening and closing of the flow path. The method of claim 1, And a pitch of the thread connecting the shaft member and the stem is formed such that the stem bed opens or closes the flow path as the operation handle is rotated at a predetermined rotation angle. The method of claim 2, The predetermined rotation angle is 180 degrees, A bellows globe valve having a pitch of 4 mm for coupling said shaft member to said stem. The method of claim 3, A bellows globe valve having a cross section of the thread having a trapezoidal shape. The method of claim 1, The end of the stem bed is formed to be inclined so as to decrease in diameter toward the bottom, the body is formed bellows globe valve inclined so that the portion in contact with the end of the stem bed corresponding to the end of the stem bed.

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