KR20240099609A - Ball valve sealing structure - Google Patents

Abstract

The present invention provides a ball that maintains stable sealing properties even when handling fluids with large temperature differences through a cylinder ring and a seal ring inserted into a seat ring and a disk spring that elastically supports the seat ring, and prevents rotational interference even when the load increases. Pertaining to a valve sealing structure, the cylinder ring is in close contact with the outer peripheral surface of the opening and closing ball; a seat ring having a first receiving groove and a second receiving groove formed on the surface, and the cylinder ring being inserted and fixed into the first receiving groove; a sealing ring in close contact with the inner wall of the valve body while being inserted and fixed into the second receiving groove; and a disk spring that elastically supports the seat ring.

Description

Ball valve sealing structure

The present invention relates to a ball valve sealing structure. More specifically, the sealing is stable even when handling a fluid with a large temperature difference through a cylinder ring and a sealing ring inserted into a seat ring and a disk spring that elastically supports the seat ring. This relates to a ball valve sealing structure that is maintained and rotational interference is suppressed even when load increases.

As shown in FIG. 1, the ball valve has an opening/closing ball (2) disposed inside the valve body (1) to select the flow path (1a) or to control the flow rate, and when such a ball valve is installed in an automated facility, a lever Instead, the opening and closing ball (2) is controlled by the actuator (3).

In addition, a valve seat (4) is provided at the connection between the opening and closing ball (2) and the flow path (1a) for sealing. In ball valves that handle fluids with a wide temperature range, the valve seat (4) is made of a material with a small linear expansion coefficient. must be used.

However, most materials with a small coefficient of linear expansion have high hardness and low elongation, so when high pressure is applied inside the flow path (1a) with the valve seat (4) made of such material, the valve seat (4) and the opening/closing ball (2) Excessive repulsive force may act on the contact surface, making precise control of the opening/closing ball (2) difficult (hereinafter referred to as 'rotational interference').

In addition, in some ball valves, such as the double sealing ball valve shown in FIG. 2 (Patent Document 1 below), the valve seat 30' is supported by a plurality of springs 42', and the repetitive opening and closing ball 20' ) Even if the valve seat 30' is worn by the rotation, the restoring force of the spring 42' presses the valve seat 30', so that sealing can be maintained.

However, a discontinuous restoring force due to a plurality of springs 42' rather than a continuous restoring force acts on the valve seat 30' of the double sealing ball valve, so wear progresses unevenly and there is a limit to the sustainability of sealing properties.

KR 10-1850883 B1 2018.04.16.

The problem to be solved by the present invention is to provide a ball valve sealing structure that maintains stable sealing properties even when handling fluids with a wide temperature range and also suppresses rotational interference even when load increases.

The ball valve sealing structure of the present invention for solving the above problems includes a cylinder ring in close contact with the outer peripheral surface of the opening and closing ball; a seat ring having a first receiving groove and a second receiving groove formed on the surface, and the cylinder ring being inserted and fixed into the first receiving groove; a sealing ring in close contact with the inner wall of the valve body while being inserted and fixed into the second receiving groove; and a disk spring that elastically supports the seat ring.

Additionally, the ball valve sealing structure of the present invention is characterized in that the seat ring is divided into a first seat ring and a second seat ring based on the second receiving groove.

Additionally, the ball valve sealing structure of the present invention is characterized in that an inclined surface is formed on the first seat ring.

In addition, the ball valve sealing structure of the present invention is characterized in that a step is formed on the outer peripheral surface of the second seat ring, and the outer end of the disk spring selectively presses the step.

According to the ball valve sealing structure of the present invention, sealing is achieved through a cylinder ring and a sealing ring that seal the opening and closing balls and the valve body, respectively, when inserted into the seat ring, a seat ring with an inclined surface, and a disc spring that supports the seat ring. Since it remains stable and rotational interference is suppressed even when the load increases, the operational reliability and management efficiency of the valve system equipped with the sealing structure of the present invention are improved.

Figure 1 is a cross-sectional view showing a ball valve sealing structure according to the prior art.
Figure 2 is an exploded perspective view showing a conventional double sealing ball valve.
Figure 3 is a cross-sectional view showing a case where the seat ring is integrated in the ball valve sealing structure according to the present invention.
Figure 4 is a cross-sectional view showing a case where the seat ring is of a split type in the ball valve sealing structure according to the present invention.
Figure 5 is an enlarged cross-sectional view of portion A of Figure 4.
Figure 6 is an enlarged cross-sectional view of part B of Figure 4.

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

Figure 3 is a cross-sectional view showing a case where the seat ring is integrated in the ball valve sealing structure according to the present invention, and Figure 4 is a cross-sectional view showing a case where the seat ring is a split type in the ball valve sealing structure according to the present invention. FIG. 5 is an enlarged cross-sectional view of portion A of FIG. 4, and FIG. 6 is an enlarged cross-sectional view showing the main portion of the ball valve sealing structure according to the present invention.

Referring to FIGS. 3, 4, 5, and 6, the present invention is a sealing structure provided in a ball valve, and the same sealing function as the previously mentioned valve seat 4 is provided by a cylinder ring 10 and a seat ring 20. ) and the sealing ring 30 share the responsibility, and the disk spring 40 presses the seat ring 20 in the direction of the opening and closing ball 2.

That is, in a state where the cylinder ring 10 and the sealing ring 30 are fixed to the seat ring 20, the cylinder ring 10 is attached to the opening and closing ball 2, and the sealing ring 30 is attached to the valve body 1. They fit closely together to prevent fluid leakage.

In addition, even when the elastic properties of the seat ring 20 change due to excessive changes in fluid temperature or the fluid pressure fluctuates excessively, the restoring force (F) of the disk spring 40 and the accompanying derivative force (Fn, f ₁ , f ₂ ), the sealing properties of the cylinder ring 10 and the sealing ring 30 are maintained stably.

Hereinafter, the specific details of the present invention will be described focusing on the above components. First, the cylinder ring 10 is a cylindrical sealing member with a predetermined width w, and one end is inserted and fixed into the seat ring 20. The other end is in close contact with the outer peripheral surface of the opening/closing ball (2) to prevent leakage between the internal passage (2a) of the opening/closing ball (2) and the passage (1a) of the valve body (1).

For this purpose, the contact surface of the cylinder ring 10 with the opening and closing ball 2 is manufactured as a curved surface corresponding to the spherical surface of the opening and closing ball 2.

In addition, in the present invention, leakage between the internal passage (2a) of the opening and closing ball (2) and the passage (1a) of the valve body (1) is prevented through the combination of the cylinder ring (10) and the seat ring (20), The cylinder ring (10), which is in close contact with the opening/closing ball (2), is made of a hard material with enhanced wear resistance compared to the existing valve seat (4), but the seat ring (20) compensates for the insufficient elasticity of the cylinder ring (10). The sealability and durability of the sealing structure can be improved.

The seat ring 20 is manufactured in a cylindrical shape corresponding to the flow path 1a, and its surface has a first receiving groove 20a for inserting and fixing the cylinder ring 10 and a first receiving groove 20a for inserting and fixing the seal ring 30. 2 Receiving grooves 20b are formed.

However, when the sealing structure of the present invention is installed in an environment with a wide temperature range, the seat ring 20 is required to be made of a material with a low coefficient of linear expansion. Most materials with a low coefficient of linear expansion have high hardness and low elongation. 2 It may be difficult to insert and secure the sealing ring 30 into the receiving groove 20b.

In order to solve this problem, the present invention may be disclosed in a configuration in which the seat ring 20 is divided into a first seat ring 21 and a second seat ring 22 based on the second receiving groove 20b.

In addition, as shown in FIG. 5, if an inclined surface α is formed on the first seat ring 21, the restoring force of the dish spring 40 when the first seat ring 21 and the second seat ring 22 are coupled. The vertical component force (Fn) of the inclined surface (α) generated by (F) allows the sealing ring (30) to come into closer contact with the inner wall of the valve body (1), thereby improving the sealing performance.

The sealing ring 30 is an O-ring-shaped sealing member, and the material used is fluorinated carbon resin (PTFE: Polytetrafluoroethylene), which has excellent chemical and thermal stability.

On the other hand, when the seat ring 20 is launched as an integrated type rather than the aforementioned split type, the insertion operation of the seal ring 30 into the second receiving groove 20b is performed by placing the seal ring 30 in a high temperature chamber and softening it. Then, increase the outer diameter using a dedicated jig and fix it in the second receiving groove (20b) using an interference fit method.

The dish spring 40 has one end elastically supported by the piping connection flange 5 and the other end is in close contact with the seat ring 20.

As mentioned earlier, even if the wear resistance of the cylinder ring 10 is strengthened, wear due to long-term use cannot be avoided. By uniformly pressing, the wear progresses to a shape corresponding to the spherical surface of the opening/closing ball 2, so that sealing can be maintained for a long period of time.

In addition, when the pressure of the flow path (1a) increases, the restoring force (F) increases (hereinafter referred to as 'load increase'), and in conjunction with this, the repulsion force (P) of the opening and closing ball (2) increases. ) An increase in the repulsive force (P) may cause rotational interference.

Accordingly, as mentioned earlier, when an inclined surface (α) is formed on the first seat ring 21, a vertical component force (Fn) is generated by the inclined surface (α), and an increase in load is caused by the repulsion force (P) of the opening and closing ball (2). ) and the frictional resistance (f ₁ ) caused by the vertical component (Fn) share, thereby suppressing rotational interference.

As a configuration to more effectively implement this load sharing, a step 221 may be further formed on the outer peripheral surface of the second seat ring 22, as shown in FIG. 6.

That is, in the normal pressure range of the flow passage 1a, the outer end 40a of the dish spring 40 is spaced apart (d) from the inner peripheral surface of the step 221, but above a certain pressure, the outer end 40a is separated from the step 221. When is pressed so that its outer circumferential surface comes into close contact with the inner wall of the valve body (1), auxiliary friction resistance (f ₂ ) is created at the close contact surface.

Therefore, rotational interference can be suppressed by distributing and supporting the increase in load through a multi-stage structure of friction resistance (f ₁ ) and auxiliary friction resistance (f ₂ ) in addition to the repulsion force (P).

Although the preferred embodiments of the present invention have been described above, the scope of the rights of the present invention is not limited thereto, and it should be understood that the scope of the rights of the present invention extends to the scope substantially equivalent to the embodiments of the present invention. Various modifications can be made by those skilled in the art without departing from the spirit of the invention.

1: Valve body 2: Open/close ball
3: Actuator 4: Valve seat
5: Flange
10: Cylinder ring
20: Seat ring
21: first seat ring 22: second seat ring
221: Danteok
30: sealing ring
40: Disc spring

Claims (4)

In the ball valve sealing structure of a ball valve in which an opening and closing ball (2) is provided inside the valve body (1),
A cylinder ring (10) in close contact with the outer peripheral surface of the opening/closing ball (2);
A seat ring (20) having a first receiving groove (20a) and a second receiving groove (20b) formed on its surface, and the cylinder ring (10) is inserted and fixed into the first receiving groove (20a);
A sealing ring (30) in close contact with the inner wall of the valve body (1) while being inserted and fixed into the second receiving groove (20b); and
A disc spring 40 that elastically supports the seat ring 20;
A ball valve sealing structure characterized by consisting of.
According to paragraph 1,
A ball valve sealing structure, characterized in that the seat ring (20) is divided into a first seat ring (21) and a second seat ring (22) based on the second receiving groove (20b).
According to paragraph 2,
A ball valve sealing structure, characterized in that an inclined surface (α) is formed on the first seat ring (21).
According to paragraph 3,
A step 221 is formed on the outer peripheral surface of the second seat ring 22, and the outer end 40a of the dish spring 40 selectively presses the step 221. A ball valve sealing structure .