KR101379703B1 - Bonnet leakage prevention enhanced valve for blocking fluid - Google Patents

Abstract

The present invention relates to a fluid control valve having an improved bonnet leakage prevention function. The fluid control valve includes: a body having a flow path chamber having a fluid inlet path formed on one side thereof and a fluid outlet path formed on the other side thereof so as to horizontally move a fluid from the inlet path to the outlet path; a valve stem part having a disk adapted to be ascended/descended in the vertical direction of the body at the center between the inlet path and the outlet path so as to control the movement of the fluid; a yoke assay part having a hand wheel mounted on the upper end thereof so as to adjust the ascending/descending of the disk and a screw path formed on the lower end thereof so as to be screw-coupled to the body; a bonnet part located close to the lower end portion of the yoke assay part and the upper end portion of the body in such a manner as to prevent the descending inside the yoke assay part and the body by means of a first protrusion formed on the body, the bonnet part having a hole formed at the inside thereof in such a manner as to allow the valve stem part to be passed therethrough; and a plurality of rings sequentially laminated on one side of the bonnet part to allow the pressure transmitted upward from the flow path chamber to be sealed and adapted to prevent the ascending thereof by means of a second protrusion formed in the body. Accordingly, thermal expansion is minimized not through surface contact, but through line contact, and even if the thermal expansion occurs, the sealing force for the pressure is increased. Further, no retainer is needed to provide easy assembling/disassembling upon maintenance, and after a sealing is removed, exchanging work can be directly performed.

Description

BONNET LEAKAGE PREVENTION ENHANCED VALVE FOR BLOCKING FLUID}

The present invention relates to a valve installed in the middle of the pipe to interrupt the supply of high-temperature, high-pressure fluid, and more particularly, to prevent leakage by maintaining the air tightness for high temperature, high pressure, and easy to replace and replace bonnet leakage The present invention provides an enhanced valve for controlling a fluid.

The gate valve generally used has a structure that vertically moves the disk provided at the lower end due to the operation of the handwheel as shown in FIG. 1 and controls the flow of the fluid horizontally due to the vertical movement. .

In order to manufacture such a valve, a process of attaching the bonnet part 11 to the body part 13, a process of stacking the sealing 17 at one end of the bonnet part 11, and a spacer ring at the top of the sealing 17 ( 16) the process of laminating, the process of laminating the split ring 15 on the top of the spacer ring 16, the retainer 20 is laminated on the top of the split ring 15 and through screwing using screws 21 The yoke assay part 12 and the body part 13 are coupled by fixing the retainer 20 and the bonnet part 11, stacking the yoke assay part 12, and screwing using the screws 14. It is accompanied by the process of making.

When the valve is assembled and installed at the production site by such a process to operate the valve, fluid and pressure exist in the body part 13, and this pressure is applied to the lower part of the bonnet part 11 and the split ring ( 15 is always fixed to compress the spacer ring 16 and the sealing 17 so that the fluid does not flow to the upper portion of the bonnet part 11.

On the other hand, the split ring 15, which is always fixed in this way, is divided into half and inserted into the valve, and for the maintenance of the valve, the hole of the body portion 13 is separated by using a separate tool. Taking out the split ring 15, removing foreign matters, and polishing the surface is required, and thus, there is a problem that the maintenance is not easy under the existing valve structure.

In other words, domestic and foreign power generation plant market needs to replace aging parts and parts of valves more easily and quickly due to short maintenance period of valves. There is also a problem.

In addition, during use of the valve, leakage may occur in the bonnet part 11 at a specific point in time. When such leakage occurs, the sealing 17 may be compressed by tightening the screw 21 to lift the bonnet part 11. This is because the sealing 17, which is the primary means for preventing leakage, is damaged, and thus there is a problem that it cannot be seen as a solution for ultimately preventing or blocking leakage.

In addition, since the lower end surface of the lowermost sealing 17 is in the form of a plane, leakage due to high temperature and high pressure is easily generated, and wear is more severe when leaking, and there is a problem in that foreign matter is severely generated.

The present invention has been made to solve the above problems, an object of the present invention, to maximize the sealing effect of the bonnet to prevent the leakage of the fluid completely from the pressure of the fluid and to prevent the bonnet leakage having a bonnet structure that is easy to disassemble and assemble The present invention provides an enhanced valve for controlling a fluid.

Fluid control valve according to an embodiment of the present invention for achieving the above object, the inflow passage of the fluid is formed on one side and the outflow passage of the fluid is formed on the other side in the horizontal direction from the inflow passage to the outflow passage A body part provided with a flow path chamber for moving the fluid; A valve stem portion which is moved up and down in the vertical direction of the body portion at the center of the inflow passage and the outflow passage, and a disc is formed to control movement of the fluid through the elevation; A yoke assay portion having a handwheel for adjusting the elevating and lowering of the disc at an upper end thereof, and a screw passage for screwing the body portion at the lower end thereof; Positioned to be adjacent to the lower end of the yoke assay and the upper end of the body portion, the yoke assay and the body portion is formed to prevent the lowering by the first protrusion provided in the body portion, the valve stem portion therein Bonnet portion provided with a hole for penetrating; And a plurality of rings sequentially stacked on one side of the bonnet part such that pressure transmitted from the flow path chamber to the upper part is hermetically sealed, and a rise is prevented by a second protrusion provided in the body part.

Here, the lowermost ring of the plurality of rings is expanded by the pressure penetrated into the space between the body portion and the bonnet portion, and between the plurality of rings and the bonnet portion and between the plurality of rings and the body portion. In order to increase the airtight force by covering the pressure to be delivered, the bottom may be a metal C-ring formed to have an open structure.

In addition, the bonnet portion is formed so as not to be coupled to the yoke assay portion and coupled to each other without being coupled to each other, when the pressure is transmitted to the upper portion from the flow path chamber, the laminated on one side of the bonnet portion When the plurality of rings are blocked together by the second protrusion provided on the body part, the lifting is blocked together, and when the pressure transmitted from the flow path chamber to the upper part is not generated, the gravity is caused by the first protrusion. It can be formed so that lowering is prevented.

As such, by using the C-ring in the valve for fluid control, thermal expansion is minimized through line contact rather than surface contact, and even when thermal expansion occurs, the airtight force against pressure is further increased, and a retainer is not required, thus maintaining and repairing It is easy to disassemble and assemble and can be replaced immediately after removing the sealing.

1 is a view showing a valve for fluid control according to the prior art.
2 is a view showing a valve for fluid regulation according to an embodiment of the present invention.
3 is a view showing a valve for fluid regulation according to another embodiment of the present invention.

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

2 is a view showing the structure of a gate valve according to an embodiment of the present invention.

As shown, the gate valve according to the present embodiment includes the bonnet part 110, the yoke assay part 120, the body part 130, the screw 140, the split ring 150, the spacer ring 160, and the C-. Ring 170 and valve stem 180.

First, as shown in the body portion 130, an inflow path through which fluid flows is formed on the left side, and an outflow path through which fluid flows out on the right side is formed. The flow path chamber through which fluid flows is provided in the center part.

When the fluid is moved through the flow path through the flow path in the inflow path, the inflow and outflow of the fluid is interrupted by the disk provided at the lower end of the valve stem 180.

The valve stem portion 180 is vertically formed at the center of the body portion 130 so that the disk is lifted up and down in the vertical direction at the center of the inflow passage and the outflow passage. This is cracked down or released.

The lower end of the valve stem portion 180 is provided with a disk, while the upper end of the valve stem portion 180 is provided with a yoke assay portion 120.

The yoke assay portion 120 is provided with a handwheel for controlling the lifting and lowering of the disk in the upper end to take charge of the axis of the valve, and a screw passage for screwing the body portion 130 is provided at the lower end. That is, the yoke assay part 120 is formed to be adjacent to the bonnet part 110 in some respects, but is not directly coupled to the bonnet part 110. For this reason, it is easy to disassemble the bonnet part 110 later and to maintain the split ring 150, the spacer ring 160, and the C-ring 170 stacked on the upper part of the bonnet part 110. You lose.

On the other hand, for fixing the valve, the yoke assay portion 120 is screwed through the body portion 130 and the screw 140. The body portion 130 is also formed to be adjacent to the bonnet portion 110 in some respects, but is not directly coupled to the bonnet portion 110. For this reason, it is easy to disassemble the bonnet part 110 later and to maintain the split ring 150, the spacer ring 160, and the C-ring 170 stacked on the upper part of the bonnet part 110. You lose.

That is, the upper end of the valve is composed of the yoke assay portion 120 and the lower portion of the body portion 130, the yoke assay portion 120 and the bonnet portion 110 in the interior surrounded by the body portion 130 And, the bonnet portion 110 is not directly coupled to the yoke assay portion 120 or the body portion 130, only the external yoke assay portion 120 and the body portion 130 screw 140 Since it is screwed together, it is not necessary to release a large number of screws, and maintenance becomes easy.

Hereinafter, a description will be given of how the bonnet part 110 is fixed inside the valve without being screwed with the yoke assay part 120 or the body part 130.

First, a process of placing the bonnet part 110 on the body 130 for the manufacture of the valve is performed. For mounting, the body portion 130 has a protrusion having protrusions formed inwardly therein. Since the bonnet part 110 is mounted to the protruding portion of the body 130, the bonnet part 110 may be prevented from moving or moving downward by gravity.

Next, a process of stacking the C-rings 170 on one end of the bonnet part 110 is performed. The C-ring 170 is firstly stacked on the bottom of the plurality of rings stacked on the top of the bonnet part 110 to be first affected by the high temperature and high pressure transmitted from the body part 130.

On the other hand, the C-ring 170 is a ring having a cross-section 'C' shape is specifically made of a metal material of the cross-section of the '∩' shape so as to have a structure in which the lower end is opened in the 'C' shape. By using the C-ring 170, which is open at the bottom as described above, the following effects can be obtained.

First, when the hydraulic pressure of the high temperature and high pressure is transmitted from the body portion 130, since the lower end is opened, the hydraulic pressure is embedded into the '∩' shape. Although the C-ring 170 is made of metal, the hydraulic pressure of the high pressure is transmitted so that the hydraulic pressure of the C-ring 170 is increased according to the degree of hydraulic pressure transmitted, thereby expanding the interior of the '∩' shape. As a result, the distance between the two ends becomes further apart.

For this reason, as the hydraulic pressure increases, the C-ring 170's original purpose of sealing and airtightness can be more faithfully performed.

In addition, since both ends face hydraulic oil in a linear form, the degree of deformation and abrasion caused by hydraulic pressure is smaller than that of a conventional surface.

When the stacking of the C-rings 170 is completed, the spacer ring 160 and the split ring 130 are sequentially stacked. Among them, the split ring 130 is stacked on the top of the plurality of rings stacked on the top of the bonnet part 110, and specifically, the bottom of another protrusion having protrusions formed inwardly in the body 130. Laminated to be formed on.

As such, the C-ring 170, the spacer ring 160, and the split ring 170 are sequentially stacked on the top of the bonnet part 110, and the uppermost split ring 170 is formed of another protrusion of the body part 130. Because it is provided at the bottom, even if the force to lift the bonnet portion 110 by the hydraulic pressure can be prevented from moving or moving in the upward direction.

Meanwhile, according to the valve according to the present embodiment, the yoke assay unit 120 and the body unit 130 are simply coupled to each other, so that the quick disassembly of both is possible. After lifting the assay unit 120, the C-ring 170, the spacer ring 160, and the split ring 170 stacked on top of the bonnet unit 110 may be sequentially taken out and maintained.

3 is a view showing a valve for fluid regulation according to another embodiment of the present invention. Hereinafter, a description will be given focusing on a part distinguished from FIG. 2.

As shown, the gate valve according to the present embodiment also includes a bonnet part 110, a yoke assay part 120, a body part 130, a screw 140, a split ring 150, a spacer ring 160, and a C- Ring 170 and valve stem 180.

In this embodiment also for mounting, the body portion 130 will have a protrusion with a protrusion formed inward. Since the bonnet part 110 is mounted to the protruding portion of the body 130, the bonnet part 110 may be prevented from moving or moving downward by gravity.

Next, the C-ring 170, the spacer ring 160, and the split ring 130 are sequentially stacked. Among these, the split ring 130 is stacked on the top of the plurality of rings stacked on the top of the bonnet part 110, and specifically, the split ring 130 is stacked to be directly adjacent to the yoke assay part 120 at the top.

As such, the C-ring 170, the spacer ring 160, and the split ring 170 are sequentially stacked on the upper end of the bonnet part 110, and the yoke assay part 120 is stacked on the uppermost split ring 170. Due to this, even if a force for lifting the bonnet part 110 by the hydraulic pressure can be prevented from moving or moving in the upward direction.

In particular, in the present embodiment, since the yoke assay part 120 and the body part 130 can be quickly disassembled, when replacing or removing foreign substances to the internal units, the yoke assay part 120 is simply lifted up and then the bonnet part ( The C-ring 170, the spacer ring 160, and the split ring 170 stacked on top of the 110 may be sequentially taken out and maintained. Accordingly, the uppermost split ring 170 is formed in a single ring shape, so that it is easier to disassemble and assemble the structure, which is divided into left and right by half, and to take out the spacer ring 160. There is no need to provide a separate hole in the body portion 130.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

11: bonnet part 12: yoke assay part
13 body portion 14 screw
15: split ring 16: spacer ring
17 sealing 18 valve stem
20: Retainer 21: Screw
110: Bonnet section 120: York assay section
130: body portion 140: screw
150: split ring 160 spacer ring
170: C-ring 180: valve stem

Claims (3)

A body part having a flow path chamber for moving the fluid in a horizontal direction from the inflow path to the outflow path by forming an inflow path of the fluid on one side and an outflow path of the fluid on the other side;
A valve stem portion which is moved up and down in the vertical direction of the body portion at the center of the inflow passage and the outflow passage, and a disc is formed to control movement of the fluid through the elevation;
A yoke assay portion having a handwheel for adjusting the elevating and lowering of the disc at an upper end thereof, and a screw passage for screwing the body portion at the lower end thereof;
Positioned to be adjacent to the lower end of the yoke assay and the upper end of the body portion, the yoke assay and the body portion is formed to prevent the lowering by the first protrusion provided in the body portion, the valve stem portion therein Bonnet portion provided with a hole for penetrating; And
And a plurality of rings sequentially stacked on one side of the bonnet part so that pressure transmitted from the flow path chamber to the upper part is hermetically sealed, and a rise is prevented by a second protrusion provided in the body part.
The lowermost ring of the plurality of rings,
Expanded by the pressure penetrated into the space between the body portion and the bonnet portion to cover the pressure transmitted between the plurality of rings and the bonnet portion and between the plurality of rings and the body portion to increase the airtight force In order to, the lower end is a fluid control valve, characterized in that the C-ring of the metal material is formed to have an open structure. delete A body part having a flow path chamber for moving the fluid in a horizontal direction from the inflow path to the outflow path by forming an inflow path of the fluid on one side and an outflow path of the fluid on the other side;
A valve stem portion which is moved up and down in the vertical direction of the body portion at the center of the inflow passage and the outflow passage, and a disc is formed to control movement of the fluid through the elevation;
A yoke assay portion having a handwheel for adjusting the elevating and lowering of the disc at an upper end thereof, and a screw passage for screwing the body portion at the lower end thereof;
Positioned to be adjacent to the lower end of the yoke assay and the upper end of the body portion, the yoke assay and the body portion is formed to prevent the lowering by the first protrusion provided in the body portion, the valve stem portion therein Bonnet portion provided with a hole for penetrating; And
And a plurality of rings sequentially stacked on one side of the bonnet part so that pressure transmitted from the flow path chamber to the upper part is hermetically sealed, and a rise is prevented by a second protrusion provided in the body part.
The bonnet part,
It is formed to be adjacent to each other in a state that is not coupled to the yoke assay portion and the body portion through screwing,
When the pressure transmitted from the flow path chamber to the upper portion is generated, the rise is prevented together because the plurality of rings stacked on one side of the bonnet part are blocked by the second protrusion provided on the body part.
And when the pressure transmitted from the flow path chamber to the upper portion is not generated, a drop due to gravity is prevented by the first protrusion.

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