KR200310666Y1 - Seat of bidirectional butterfly valve having inside elastic member - Google Patents

Abstract

The present invention relates to a two-way butterfly valve, the protrusion is formed on the outer peripheral surface of the seat, the indentation is formed to be eccentric with the center of the seat on the inner peripheral surface, the deformation portion and the deformation space is formed in the middle portion, the elastic member Increasing elasticity by elastic member increases the restoring force of the seat, and makes the seat and valve disc contact smoothly due to the elasticity of the seat even in long-term use, which prevents the wear of the seat and thereby improves the sealing performance. It can be.

The present invention also relates to a seat structure of a bidirectional butterfly valve having a resilient member embedded therein, which greatly increases the adaptability of the seat according to the flow direction of the fluid due to the elasticity of the seat to maximize watertightness even when the valve is used in both directions.

Description

Seat structure of bidirectional butterfly valve with elastic member {Seat of bidirectional butterfly valve having inside elastic member}

The present invention relates to a bidirectional butterfly valve, and more particularly, by incorporating a ring-like resilient member into the seat of the Teflon material to maintain the watertightness of the valve, thereby increasing the flexibility and resilience of the seat, and always at high temperature or high water pressure. The seat structure of a bidirectional butterfly valve with a built-in elastic member that can maintain a perfect water tightness.

In general, a butterfly valve is installed with a butterfly valve which can smoothly open and close the valve when the flow of various fluids such as industrial water, oil, or sea water is blocked or opened.

The butterfly valve used in this way must be sealed by the valve disc and seat when the fluid is shut off to maintain the water tightness. The seat is a sheet of Teflon material made of a relatively hard material that can withstand high temperature fluids and high pressure or chemicals. Is being used.

The seat structure for maintaining the water tightness of the butterfly valve generally used for this sealing effect is the inner circumferential surface of the conventional valve body 100, the valve disk 200 is formed by the rotating shaft in the middle as shown in Figure 1 The seat 300 of the Teflon material is fixed by the separate seat fixing plate 400 to the outer circumferential surface of the valve disc 200 to press the seat 300 to be sealed.

However, the above-mentioned butterfly valve seat has a hard material, the elasticity of the seat decreases when the valve disc opens and closes, and the restoring force of the seat decreases. This problem is deteriorated.

In addition, there is a problem in that the seat is not suitable for use because the adaptive force of the seat due to the flow of fluid due to the decrease in elasticity of the seat in the bidirectional use of the valve.

The present invention is a bidirectional butterfly valve, which is devised to solve the above problems, the protrusion is formed on the outer peripheral surface of the seat, the inner circumferential surface to form an indentation to be eccentric with the center of the seat, the deformable portion and By forming a deformation space, by inserting the elastic member into the press-fitting part, the elasticity by the elastic member to increase the restoring force of the seat, and even when used for a long time, the contact between the seat and the valve disk by the seat elasticity to smooth the It can prevent abrasion and increase sealing performance.

In addition, the seat elasticity of the two-way butterfly valve incorporating a resilient member that can maximize the water tightness even when used in both directions of the valve by significantly increasing the adaptability of the seat according to the flow direction of the fluid by the elasticity of the seat There is a purpose.

1 is a seat structure of a conventional butterfly valve

2 is an exploded perspective view of the present invention.

3 is a cross-sectional view of the seat of the present invention.

4a and 4b is an explanatory view showing a seat operating state of the present invention,

4A is an explanatory view of the sheet operation in the forward flow.

4B is an explanatory diagram of the sheet operation in the reverse flow;

<Description of Symbols for Main Parts of Drawings>

1: body 2: valve disc

3: sheet 4: sheet fixing plate

5: elastic member 6,6 ': stone

7: deformation part 8: deformation space

9: press-fitting part 10: groove groove

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

1 is a conventional seat structure of the present invention, Figure 2 is an exploded perspective view of the valve and the seat of the present invention, Figure 3 is a cross-sectional explanatory view of the seat of the present invention, Figures 4a and 4b is the positive direction of the fluid of the seat of the present invention It is cross-sectional explanatory drawing which showed the operation | movement state of the sheet by the flow of reverse direction.

In the known butterfly valve in which the seat 3 is inserted by the seat fixing plate 4 on the inner circumferential surface of the body 1, and the valve disc 2 which can be opened and closed by an axial rod is built up.

Protrusions 6 and 6 'are formed on both sides of the outer circumferential surface of the sheet 3, and indentations 9 are formed on the inner circumferential surface of the seat 3 so as to be eccentric with the center of the sheet 3, and the protruding portions 6 and 6' The deformation portion 7 and the deformation space 8 are formed in the middle portion of the press-fit portion 9,

The ring-shaped resilient member 5 is embedded in the press-fitting portion 9, and the recessed groove 10 is formed inside the seat fixing plate 4.

In addition, the elastic member 5 embedded in the press-in portion 9 can be formed by a coil spring.

Hereinafter, the configuration will be described in more detail with reference to the drawings.

As shown in FIG. 2, the butterfly valve is composed of a valve disc 2 arranged inside the body 1 by an axial rod and a seat 3 fixed by a seat fixing plate 4.

At this time, the valve disk (2) built up by the shaft is made of the same configuration and operation as a general conventional butterfly valve.

On the other hand, the seat (3) for contacting the valve disc (2) to maintain the water tightness of the fluid when the valve disc (2) rotates open and closed is a ring shape coupled to the inner peripheral surface of the body (1), as shown in FIG. The protrusions 6 and 6 'are formed on both sides of the outer periphery of the seat 3 by the body 1 and the seat fixing plate 4 so that the seat 3 can be fixed in the body 1 without detachment. The ring-shaped resilient member 5 is eccentrically inserted at the center of the sheet in the cross section inside the press-fitted portion 9 of the inner circumferential surface, and the protrusion 6, 6 'and the resilient member 5 of the seat are embedded. In the middle of the (9) to increase the elasticity of the sheet to form a deformation portion 7 is thin in thickness, and the deformation space (8) is formed on the inside to maximize the resilience and flexibility of the sheet.

In addition, the seat fixing plate 4 for fixing the seat 3 and the body 1 is formed on the inner side of the valve disk (2) by forming the groove groove 10 as shown in Figure 4a and 4b It is to ensure a smooth sealing when the sheet is pressed.

On the other hand, the present invention described above is shown in accordance with the action of the forward and reverse hydraulic pressure as shown in Figures 4a and 4b, as shown in Figure 4a when the flow of fluid in the forward direction is generated a valve disk is closed The fluid flows into the space of the body 2 and the body 1, whereby the hydraulic pressure of the fluid is applied to the seat 3, and the press-fitting part 9 into which the resilient member 5 of the seat 3 is inserted is a fluid. By the hydraulic pressure of the inclined portion of the valve disc 2 and the body (1) will be pressed.

At this time, since the seat 3 is deformed in the direction in which the fluid flows around the deformable portion 7, the distance from the valve disc 2 tends to be far, but the valve disc 2 also moves in the same direction by hydraulic pressure. In this way, the inclined surface of the valve disc 2 cancels the distance and shortens the distance, so that the press-fitting portion 9 into which the elastic member 5 of the seat 3 is inserted is desired by the deformation space 8. It is pressed into the inclined portion and the body 1 of the valve disc 2 is to be tightly sealed.

In addition, when the fluid flows in the reverse direction as shown in FIG. 4B, the hydraulic pressure generated therein is introduced into the space of the valve disc 2 and the body 1 as in the case of the forward flow. (3), the seat (3) is extended by the deformation of the deformation space (8) around the deformation portion (7) by the hydraulic pressure of the fluid to offset the distance to relax by moving the valve disc (2) The press-fitting portion 9 into which the elastic member 5 of the seat 3 is inserted is press-fitted into the inclined portion of the valve disc 2 and the recessed groove 10 of the seat fixing plate 4 so as to have a shorter effect. A tighter seal can keep the fluid tight.

On the other hand, the deformation portion 7 and the deformation space formed in the middle portion of the sheet 3 is more desirable for the indentation portion 9 into which the elastic member 5 of the sheet is inserted when the sheet 3 is pushed left and right by water pressure. It is possible to increase the adhesion by the elastic force, the elastic member 5 embedded in the indentation (9) is to improve the sliding and restoring force of the seat (3) in accordance with the opening and closing of the valve disc (2).

As described above, the present invention increases the elasticity of the seat 3 of the hard Teflon material for maintaining the watertightness of the butterfly valve, thereby maintaining the watertight due to the hydraulic pressure of the fluid with a more smooth and stable optimum sealing effect even in the bidirectional use of the valve. I can give it.

As described above, the present invention increases the restoring force of the seat due to the increase of elasticity by the elastic member, and the seat elasticity of the seat facilitates contact between the seat and the valve disc even when used for a long period of time, thereby preventing seat wear and thereby sealing performance. In addition, the elasticity of the seat can significantly increase the adaptability of the seat according to the flow direction of the fluid, thereby obtaining the effect of maximizing water tightness even when used in both directions of the valve.

Claims (3)

In the known butterfly valve in which the seat 3 is inserted by the seat fixing plate 4 on the inner circumferential surface of the body 1, and the valve disc 2 which can be opened and closed by an axial rod is built up. Protrusions 6 and 6 'are formed on both sides of the outer circumferential surface of the sheet 3, and indentations 9 are formed on the inner circumferential surface of the seat 3 so as to be eccentric with the center of the sheet 3, and the protruding portions 6 and 6' The deformation portion 7 and the deformation space 8 are formed in the middle portion of the press-fit portion 9, The seat structure of the two-way butterfly valve in which the elastic member is embedded, characterized in that the ring-like elastic member (5) is built in the press-fit portion (9). 2. The seat structure of a bidirectional butterfly valve incorporating a resilient member according to claim 1, wherein the resilient member (5) embedded in the press-fitting portion (9) is formed by a coil spring. 2. The seat structure of a bidirectional butterfly valve incorporating a resilient member according to claim 1, characterized in that a recess groove (10) is formed inside the seat fixing plate (4).