RU2690325C2 - Protective assembly for sealing seat gasket and pressure regulator - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: disclosed is group of inventions called protective assembly for seal seat valve seat gasket and pressure regulator. This protective assembly comprises: a valve channel and a valve seat, wherein the valve seat comprises a sealing gasket, and sealing gasket contains a vulnerable area located on outlet side of valve channel. Protective assembly additionally comprises protective ring and first valve cage, wherein this protective ring partially covers the sensitive area of the sealing gasket, and the first valve cell is configured to fix the protective ring on the valve seat.EFFECT: protective ring partially envelopes sensitive area of sealing gasket, therefore in operating conditions with high pressure drop, protective assembly can prevent damage to sealing gasket with long-acting high-pressure medium jet so as to avoid destruction of internal seal.14 cl, 16 dwg

Description

Technical field

This utility model relates to the field of pressure regulators, and, in particular, to the protective node for sealing the valve seat, as well as to the pressure regulator.

The level of technology

In existing pressure regulators and valves that require a tight shut-off, in most cases an elastic sealing gasket and a metal valve channel are used to create a seal. As shown in FIG. 1, a sealing gasket 13 is located on the seat 12 of the valve of the pressure regulator 1. The material of the gasket 13 is usually a rubber. As a rule, the state of resilient sealing materials, such as rubber, is adversely affected by the impact of a high-pressure high-velocity jet of the medium. In particular, under the operating conditions of a gas medium with a large pressure drop after a decrease in the pressure of the gas medium, the temperature significantly decreases as compared with the temperature at high pressure. Under conditions of low temperature, the elasticity of rubber deteriorates and it is quite easily damaged. According to FIG. 1, when the opening of the valve channel is relatively small, and the pressure difference between the inlet and outlet is relatively large, after passing through a narrow gap formed by the valve channel 11 and the gasket 13, the high-pressure medium enters a relatively large space, the pressure of the medium quickly decreases, the medium spreads explosively , the flow rate increases rapidly and at the same time the temperature drops rapidly. When exposed to high-speed low-temperature jet of the medium, the part of the gasket 13 located on the outlet side is quickly damaged and destroyed. Thus, the impact of a high-speed low-temperature jet of the medium caused by a large pressure drop is the main cause of a leak in the gasket and the life of the gasket can be significantly increased by limiting the pressure difference between the inlet and the outlet of the pressure regulator. However, some high-pressure valves or pressure regulators are designed for use in environments with large pressure drops, and therefore other methods need to be offered to protect the gasket.

Disclosure of the invention

This utility model provides a protective assembly for a valve seat gasket, as well as a pressure regulator that solves the above existing problem of seal failure caused by a damage to the gasket.

The protective assembly comprises a valve channel and a valve seat, the valve seat comprising a sealing gasket; moreover, the sealing gasket contains a vulnerable area located on the outlet side of the valve channel, and moreover, the protective assembly further comprises a protective ring, and this protective ring partially covers the vulnerable area of the sealing gasket.

The first protrusion is located on the first part of the protective ring of the protection assembly, the first part being located on the surface of the valve channel.

The cross section of the first protrusion of the security assembly in the vertical direction is a trapezoid, a rectangle or a triangle.

The angle corresponding to the contiguous part between the first protrusion and the sealing gasket of the protective assembly, in the cross section of the first protrusion in the vertical direction, is rounded or beveled.

The protective assembly further comprises a first valve cage, with the first valve cage fixing the protective ring on the valve seat with the second part of the protective ring.

The cross section of the second part of the security assembly in the vertical direction is L-shaped or L-shaped, with the second part comprising a first end portion in the vertical direction and a second end portion in the horizontal direction, the first end portion being connected to the first part, and the second end portion the part is in contact with the first valve cage or valve seat.

The cross section of the second part of the protective assembly in the vertical direction is L-shaped, the first groove is located on the contacting part between the first valve cage and the protective ring, and the second end part is inserted into the first groove; and

the cross section of the second part in the vertical direction is L-shaped, the second groove is located on the contacting part between the valve seat and the second part, and the second end part is inserted into the second groove.

The guard ring is integrated with the valve seat of the guard assembly; or

the protective assembly comprises a second valve cage, and a protective ring integrated with the second valve cage.

The protective ring of the protective assembly is fixed to the valve seat with a fastener.

The protective ring is made with the second protrusion of the protective node and is located on the surface of the valve seat.

The cross section of the second protrusion of the security assembly in the vertical direction is a trapezoid, a rectangle or a triangle.

The angle corresponding to the contiguous part between the second protrusion and the sealing gasket of the protection assembly is rounded or skewed in cross section.

The valve channel contains a working edge of the protective assembly, the cross-section of the working edge in the vertical direction is a rectangular trapezium, and the rectangular side of this rectangular trapezium is located on the side of the vulnerable area.

This utility model further comprises a pressure regulator containing any of the above mentioned safety assembly. In conditions of operation with high pressure drop and high speed over the life of the gasket can be increased.

For the protective assembly for the sealing gasket of the valve seat and the pressure regulator corresponding to the present utility model, the protective ring partially covers the vulnerable area of the sealing gasket so that the flow state of the medium in the area with high pressure drop and high-speed flow can be changed, local drop can be reduced pressure and local flow rate, and at the same time cover the vulnerable area in such a way as to significantly increase the service life of the gasket and redotvratit damage the gasket.

Brief Description of the Drawings

In FIG. 1 is a schematic representation of a prior art pressure regulator and a partial schematic of a pressure regulator;

In FIG. 2 is a partial schematic representation of a security assembly corresponding to one of the examples of the present utility model;

In FIG. 3 is a perspective view of the valve cage of the protector assembly for the sealing gasket of the valve seat shown in FIG. 2;

In FIG. 4 shows a partial schematic of a security node corresponding to one of the examples of the present utility model;

In FIG. 5 shows a partial schematic of a security node corresponding to one of the examples of the present utility model;

In FIG. 6 is a perspective view of the protective ring of the security assembly shown in FIG. five;

In FIG. 7 is a sectional view of the valve seat and the sealing gasket of the protection assembly shown in FIG. five;

In FIG. 8 shows a partial schematic of a security node corresponding to one of the examples of the present utility model;

In FIG. 9 shows a partial schematic of a security node corresponding to one of the examples of the present utility model;

In FIG. 10 is a sectional view of the valve cage of the security assembly shown in FIG. 9;

In FIG. 11 shows a partial schematic of a security node corresponding to one of the examples of the present utility model;

In FIG. 12 is a partial schematic representation of a security assembly corresponding to one of the examples of the present utility model;

In FIG. 13 is a partial schematic representation of a security assembly corresponding to one of the examples of the present utility model;

In FIG. 14 is a perspective view of the protective ring of the security assembly shown in FIG. 13;

In FIG. 15 shows a partial schematic of the security assembly corresponding to one of the examples of the present utility model;

In FIG. 16 shows a pressure regulator corresponding to one of the examples of the present invention, and a partial schematic of the pressure regulator.

The implementation of the invention

Technical solutions related to this utility model are described below with reference to the accompanying drawings and specific examples.

Example 1

This utility model is a protective unit for sealing the valve seat gasket. This protection assembly contains a valve channel and a valve seat. The valve seat contains a gasket. The gasket contains a vulnerable area, i.e., an area that is exposed to a large pressure drop and a high-speed flow, located on the outlet side of the valve channel. The protective node further comprises a protective ring, which partially covers the vulnerable area. When the valve channel is closed, it contacts the valve seat gasket to create a tight overlap. At the initial stage of opening the valve channel, its opening is relatively small, and the pressure differential between the inlet and outlet is relatively large. After passing through a narrow gap formed by a valve channel and a gasket, a high-pressure high-speed fluid flow enters into one relatively large space, the fluid pressure quickly decreases, the medium spreads explosively, the flow velocity increases rapidly and at the same time the temperature drops rapidly. In this case, the vulnerable area of the gasket, located on the outlet side of the valve channel, is exposed to high pressure drop and high-speed flow. Since the protective ring partially covers the vulnerable area of the gasket and the second valve channel formed by the protective ring and the working edge can change the local state of the fluid flow, the local pressure drop and the local flow velocity decrease, and the service life of the gasket increases.

In this example of the present utility model, the first protrusion is located on the first part of the security assembly. The first part is located on the surface of the valve seat. If the valve seat is mounted in the direction shown in the accompanying drawings, the first part of the protective ring is located on the upper surface of the valve seat. It should be understood that if the valve seat of the pressure regulator or the valve is turned upside down, the protective assembly will be located on the lower surface of the valve seat.

The cross section of the first protrusion in the vertical direction is a trapezoid, a rectangle or a triangle. Since between the working edge and the first protrusion of the protective ring in the vertical direction there is a gap and a design similar to a two-channel valve is formed, the local flow state can be changed, and the local voltage drop and the local flow velocity in the vulnerable area of the gasket are reduced so that the medium flow state after the medium escapes from the gap between the valve channel and the gasket, the local voltage drop and the local flow rate change vulnerable area of the gasket is reduced so as to prevent damage to the gasket of low-temperature high-speed jet fluid.

Preferably, the angle corresponding to the contiguous part between the first protrusion and the sealing gasket, in the cross section of the first protrusion of the protective ring, is rounded or beveled. When the valve channel is closed, the resilient gasket is pressed through the angle of the contacting part between the first protrusion and the gasket, and the design in the form of a rounded or beveled angle can prevent the gasket from cutting through when pushed through. In some cases, the angle that is located on the first protrusion and that does not come in contact with the sealing gasket may also be rounded or beveled in order to slow the flow of air.

There are many ways to install and fasten a protective ring.

The protective assembly comprises a first valve cage, the protective ring containing the second part, and the first cage of the valve fixes the protective ring to the valve seat with this second part.

In particular, the cross section of the second part in the vertical direction is L-shaped or L-shaped, the second part comprises the first end part in the vertical direction and the second end part in the horizontal direction, the first end part is connected to the first part, and the second end part Contact the first valve cage or valve seat.

If the cross section of the second part in the vertical direction is L-shaped, the first groove is located on the contacting part between the first cage of the valve and the protective ring, and the second end part is inserted into the first groove; or

if the cross section of the second part in the vertical direction is L-shaped, the second groove is located on the contacting part between the valve seat and the second part, and the second end part is inserted into the second groove.

In addition, the protective ring can be combined with the valve seat.

The safety assembly may further comprise a second valve cage, and a protective ring integrated with the second valve cage.

In addition, the protective ring can additionally be riveted to the valve seat or attached to the valve seat with a fastener.

In some cases, the protective ring may further comprise a second protrusion, the protective ring is located on the upper surface of the valve seat, and the cross section of the second protrusion in the vertical direction is a trapezoid, a rectangle or a triangle. The angle of the contiguous part between the second protrusion and the gasket is rounded or skewed.

In accordance with the present utility model, the valve channel contains a working edge of the protection assembly, with the cross-section of the working edge in the vertical direction being a rectangular trapezium, and the rectangular side of a rectangular trapezoid is located on the side of the vulnerable area. When the valve channel is closed, they can prevent the working edge and protective ring from coming in contact in order to avoid friction.

Example 2

FIG. 2 is a partial sectional view of the security assembly 20 corresponding to one of the examples of the present utility model. The protective assembly 20 comprises a valve duct 21, a valve seat 22, a sealing gasket 23 located on the valve seat 22, and a protective ring 24 adapted to protect the sealing gasket 23. The protective assembly 20 further comprises a valve cage 25 which is adjacent to the valve seat 22 . Valve cage 25 in this example may preferably be implemented in the same manner as the first valve cage in the above example.

FIG. 3 is a perspective view of valve cage 25. The assembled valve cage 25 is located on the valve seat 22 and is tightly pressed against it. In this example, the protective ring 24 comprises a first part 241 and a second part 242, the first protrusion 243 is located on the first part 241, the first protrusion 243 partially covers the vulnerable area 231 of the gasket 23, the second part 242 is adapted to adhere to the valve seat 22, and the cage 25 valve fixes the protective ring 24.

Valve channel 21 further comprises a working edge 211. When the valve channel is closed, the working edge 211 of the valve channel 21 contacts the sealing gasket 23 on the valve seat 22. Since the material of the gasket 23 is relatively elastic, in the closed position, the working edge is pressed into the gasket 23.

At the initial stage of opening the valve channel in this case, the opening of the valve channel is relatively small. If the pressure difference between the inlet and outlet is relatively large, after passing through a narrow gap formed by the valve channel and the sealing gasket, the high-pressure medium enters a relatively large space, the working medium pressure quickly decreases, the working medium spreads explosively, the flow rate quickly increases and the temperature falls fast. In this case, the protective ring partially covers the vulnerable area of the gasket and the protective ring and the working edge can additionally form a second valve channel, which allows changing the local state of the medium flow, reducing the local pressure drop and the flow rate, and the service life of the sealing can be significantly increased. pads.

The first protrusion 243 of the protective ring 24 is located near the working edge 211 of the valve channel 21, but does not come into contact with it. The cross section of the first protrusion 243 of the first part 241 in the vertical direction is a rectangular trapezoid, one side of which is located on the side of the outlet cavity of the valve channel. If the opening of the valve channel is relatively small, the high-pressure medium first enters the outlet cavity from a narrow gap in the horizontal direction. Since the first protrusion of the first part 241 of the protective ring 24 is located on the outer side of the working edge, after colliding with the first protrusion, the flow of the high-pressure medium turns upwards, so that the local flow state changes in comparison with the original design, the initial local voltage drop decreases and the initial local flow rate the vulnerable area of the gasket and a second valve channel arises. At the same time, the valve seat gasket is partially closed to prevent a large pressure drop and high velocity flow from affecting the gasket to avoid damage and destruction.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction may also be a rectangle. The first protrusion, the cross section of which is a rectangle, has a certain height, so that the second valve channel can be formed thinner and longer, which allows to enhance the effect of "reducing the local differential pressure and the local flow velocity" of the second valve channel.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction can also be a triangle.

The second part 242 of the protective ring 24 comprises a first end portion in the vertical direction and a second end portion in the horizontal direction, the cross section of the second portion in the vertical direction being L-shaped, and the first end portion is connected to the first part 241. In this case, the first groove located on the contacting part between the second part and the valve cage. The second end part is inserted into the first groove. When the protective assembly is assembled, the valve cage can be tightly pressed and fixed on the valve seat with a protective ring of the second part. Preferably, the cross section of the first protrusion of the first part in the vertical direction is a rectangle or a trapezoid that contains the upper vertex and angle, i.e. the lower vertex of the portion that comes in contact with the sealing gasket. The lower top is a rounded or beveled corner and is designed to protect the gasket from damage when the gasket is pressed by the working edge. In some cases, the upper tip may also be a rounded or beveled corner and configured to slow the flow of air. If the cross section of the first protrusion of the first part in the vertical direction is a triangle, the angle of the triangle in contact with the sealing gasket may be similarly rounded or beveled. The first protrusion, the cross section of which in the vertical direction is a triangle, a trapezoid or a rectangle, and part of the working edge of the valve channel can form a second valve channel so that the state of fluid flow after the medium flows out of the gap between the valve channel and the gasket changes, and the local the voltage drop and local flow rate on the vulnerable area of the gasket are reduced, which helps prevent damage to the gasket .

The advantage of this example is that: In one aspect, the first protrusion of the protective ring covers the vulnerable area of the gasket 23, thereby protecting the gasket from the effects of a strong direct jet. In another aspect, the second valve channel formed by the first protrusion of the protective ring and the working edge changes the local state of the fluid flow in such a way as to reduce the local pressure drop and the local flow rate (this can significantly increase the service life of the gasket), thus preventing damage sealing gasket due to the large pressure drop of the medium that flows at high speed. In this example, the method of fixing the protective ring is that the protective ring is partially pressed tightly against the valve seat using a valve cage.

Example 3

FIG. 4 is a partial sectional view of the protective assembly 30 for sealing the valve seat in accordance with Example 3. As in Example 1, the protective assembly 30 includes a valve channel 31, a valve seat 32, a sealing gasket 33 located on the valve seat 32, a protective ring 34, configured to protect the gasket 33, and a valve cage 35 adjacent to the valve seat 32. The valve cage in this example can preferably be implemented in the same way as the first valve cage in example 1.

The protective ring 34 likewise has the first part 341 and the second part 342. The first part 341 partially covers the vulnerable area 331 of the gasket 33. The vulnerable area is affected by a large pressure drop and a high-speed flow of fluid. The second portion 342, which is combined with the first portion 341, has an L-shaped cross section in the vertical direction. The part of the second part extending in the horizontal direction is relatively long and is fully pressed and fixed on the valve seat with the help of the valve cage.

The first part 341 of the protective ring 34 in this example contains the first protrusion. The cross section of the first protrusion in the vertical direction is a rectangular trapezoid, which contains the upper vertex and angle, i.e. the lower vertex of the part that comes into contact with the sealing gasket. Preferably, the lower top is a rounded or chamfered corner and is configured to protect the gasket against damage when the gasket is pressed against the working edge. In some cases, the upper tip may also be a rounded or beveled corner and configured to slow the flow of air.

The protective ring and part of the working edge of the valve channel form the second valve channel in such a way that the state of the medium flow after the medium flows out of the gap between the valve channel and the gasket changes, and the local voltage drop and the local flow rate on the vulnerable area of the gasket decrease, which prevents damage to the gasket.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction may also be a rectangle. The first protrusion, the cross section of which is a rectangle, has a certain height, so that the second valve channel is formed thinner and longer, which allows to enhance the effect of "reducing the local differential pressure and the local flow velocity" of the second valve channel.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction can also be a triangle.

The difference from example 2 lies in the method of fixing the protective ring 34. In this example, a groove is not provided on the valve cage 35. The lower part of the valve cage is pressed directly to the second part, which in the vertical direction has an L-shaped cross-section. In this example, in the protective assembly for the valve seat gasket, the protective ring 34 can be fixed without using a groove on the valve cage.

The advantage of this example is that: In one aspect, the first part of the protective ring covers the vulnerable area of the gasket 33, thereby protecting the gasket from the effects of a strong direct jet. In another aspect, the second valve channel formed by the first protrusion of the protective ring and the working edge changes the local state of the fluid flow in such a way as to reduce the local pressure drop and the local flow rate (this can significantly increase the service life of the gasket), thus preventing damage sealing gasket due to the large pressure drop of the medium that flows at high speed. In this example, the method of fixing the protective ring is that the horizontal part of the second part of the protective ring is completely and firmly pressed against the valve seat using a valve cage.

Example 4

FIG. 5 is a partial sectional view of the protection assembly 40 corresponding to example 4. As in the above example, the protection assembly 40 for sealing the valve seat gasket in this example comprises a valve channel 41, a valve seat 42, a sealing gasket 43 inserted into the valve seat 42 protective ring 44, designed to protect the gasket 43, and the valve cage 45 adjacent to the valve seat 42. The valve cage in this example can preferably be implemented in the same way as the first valve cage in example 1.

As in the above example, the protective ring 44 has a first part and a second part, the first part covers the vulnerable area of the gasket, the cross section of the first protrusion of the first part in the vertical direction is a rectangular trapezium, which also contains the upper vertex and angle, i.e. the lower top of the part that comes into contact with the gasket. Preferably, the lower vertex is a rounded or beveled corner. When the valve channel is closed, the elastic sealing gasket is pressed through the lower top. The design in the form of a rounded or chamfered angle can prevent the sealing gasket from cutting through when it is pushed by the working edge. In some cases, the upper tip may also be a rounded or beveled corner and configured to slow the flow of air.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction may also be a rectangle. The first protrusion, the cross section of which is a rectangle, has a certain height, so that the second valve channel is formed thinner and longer, which allows to enhance the effect of "reducing the local differential pressure and the local flow velocity" of the second valve channel.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction can also be a triangle.

The difference from the above example is that the cross section of the second part of the protective ring 44 in the vertical direction is L-shaped. A second groove is provided on the side wall of the valve seat 42. Passing in the horizontal direction, the second end portion 443 of the second part is inserted into the second groove of the valve seat 42. The assembled valve cage 45 tightly presses the protective ring 44 to the valve seat 42 on the side of the side surface.

FIG. 6 is a perspective view of the protective ring 44 of this example. The protective ring 44 is formed of two half-rings, which can be appropriately inserted into the valve seat 42 shown in FIG. 7, to form a single circular protective ring. The valve stem cage inserted into the valve seat 42 is located on the outside of the protective ring 44 and can attach the protective ring 44 to the valve seat 42 on the side of the side surface.

In some cases, the guard ring may additionally contain a plurality of arc segments, and this plurality of arc segments are connected in a full circle.

The advantage of this example is that: In one aspect, the first part of the protective ring covers the vulnerable area of the gasket 43 to prevent strong direct jets from acting on the sealing gasket 43. In another aspect, the second valve channel formed by the first lip of the protective ring 44 and the working lip , changes the local state of the flow of the medium, and the local pressure drop and the local flow rate decrease (thus the service life of the sealing gasket significantly increases ki) and prevents damage to the gasket due to the large pressure drop of the medium that flows at high speed. In this example, the method of fixing the protective ring is that the protective ring is firmly pressed against the valve seat on the side of the side surface using a valve cage.

Example 5

FIG. 8 is a partial sectional view of the protective assembly 50 for sealing a valve seat gasket corresponding to example 5. The protection assembly 50 in this example comprises a valve channel 51, a valve seat 52 and a protective ring 54 configured to protect the sealing gasket 53. Third groove 521 located on the valve seat 52, and the third groove 521 is configured to receive a sealing gasket 53. The protective ring 54 in this example is combined with the valve seat 52 and the first protrusion of the protective ring 54 covers the third az 521, adapted to receive the gasket 53 the valve seat 52, and the vulnerable area of the gasket 53 may be similarly protected.

As in the above example, the cross section of the first protrusion of the protective ring 54 in the vertical direction is a rectangular trapezoid. The angle, i.e. the lower top of the contiguous part between the sealing gasket and the rectangular trapezium, is rounded or skewed. When the valve channel is closed, the elastic sealing gasket is pressed through the lower top. The design in the form of a rounded or chamfered angle can prevent the sealing gasket from cutting through when it is pushed by the working edge. In some cases, the upper tip may also be a rounded or beveled corner and configured to slow the flow of air.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction may also be a rectangle. The first protrusion, the cross section of which is a rectangle, has a certain height, so that the second valve channel is formed thinner and longer, which allows to enhance the effect of "reducing the local differential pressure and the local flow velocity" of the second valve channel.

In some cases, the cross section of the first protrusion of the protective ring in the vertical direction can also be a triangle.

Example 6

FIG. 9 is a partial sectional view of the protection assembly 60 corresponding to example 6. The protection assembly 60 in this example comprises a valve passage 61, a valve seat 62, a sealing gasket 63 located inside the valve seat 62, and a valve cage 65 containing a protective ring 64. The valve cage in this example may preferably be implemented in the same manner as the second valve cage in Example 1, and the protection ring 64 comprises a second protrusion 66.

FIG. 10 is a sectional view of a valve cage 65. The protective ring 64 is combined with the valve cage 65, and a protrusion is formed at the lower end on the inside of the valve cage. In the assembled form shown in FIG. 9, a protective ring 64 on the valve cage partially encloses the vulnerable area of the gasket to protect the gasket from high pressure drop and high velocity flow in order to avoid damaging it.

As in the above example, the cross section of the first protrusion 66 of the protective ring 64 in the vertical direction is a rectangular trapezoid. The angle, i.e. the lower top of the contiguous part between the sealing gasket and the rectangular trapezium, is rounded or skewed. When the valve channel is closed, the elastic sealing gasket is pressed through the lower top. The design in the form of a rounded or chamfered angle can prevent the sealing gasket from cutting through when it is pushed by the working edge. In some cases, the top tip, which is not in contact with the gasket, may also be a rounded or beveled corner and configured to slow the flow of air.

In some cases, the cross section of the second protrusion of the protective ring in the vertical direction can also be a rectangle. The second protrusion, the cross section of which is a rectangle, has a certain height, so that the second valve channel is formed thinner and longer, which allows to enhance the effect of "reducing the local differential pressure and the local flow velocity" of the second valve channel.

In some cases, the cross section of the second protrusion of the protective ring in the vertical direction can also be a triangle.

Example 7

FIG. 11 is a partial sectional view of the protective assembly 70 for sealing the valve seat in accordance with Example 7. As in Example 2, the protective assembly 70 for sealing the valve seat comprises a valve channel 71, a valve seat 72, a sealing gasket 73 inserted into the seat 72 valves, a protective ring 74 designed to protect the gasket 73, and a valve cage 75 adjacent to the valve seat 72. The valve cage in this example can preferably be implemented in the same way as the first valve cage in example 1.

Similarly, the protective ring 74 has a first part and a second part. The first protrusion of the first part covers the vulnerable area of the gasket 73. The second part, which is combined with the first part, has an L-shaped cross section in the vertical direction. The second end part of the second part, passing in the horizontal direction, is tightly pressed and fixed on the valve seat with the help of the valve cage.

The difference from example 2 is that the cross section of the first protrusion of the first part of the protective ring 74 in the vertical direction in this example is a rectangle. Preferably the angle, i.e. the lower top of the rectangle in contact with the sealing gasket, is designed as a rounded or beveled corner. When the valve channel is closed, the elastic sealing gasket is pressed through the lower top. The design in the form of a rounded or chamfered corner can prevent the sealing gasket from cutting through when pushed through.

The first protrusion of the protective ring in this example has a certain height. In one aspect, the first protrusion of the protective ring covers the gasket and protects the gasket from high pressure damage. In another aspect, since the first protrusion of the protective ring has a slightly larger height, the second valve channel in this solution is formed narrower and longer and changes the flow state in such a way that the effect of reducing the local voltage drop and the local flow rate is more pronounced.

The valve cage tightly presses the second part of the protective ring on the valve seat to fix the protective ring. In this example, half of the second part of the protective ring tightly presses the lower end of the valve cage, that is, the same method of fastening is used as in example 2.

In some cases, the valve cage can press the second part of the protective ring tightly against the valve seat, i.e., use the same mounting method as in example 3.

In some cases, the second part of the protective ring can also be concave towards the side of the valve seat, i.e., the same mounting method is used as in Example 4. The valve cage can firmly press the protective ring to the valve seat on the side of the side surface.

In some cases, the protective ring can also be combined with the valve seat or combined with the valve cage, provided that the first protrusion of the protective ring covers the vulnerable area of the gasket to prevent damage to the gasket.

Example 8

FIG. 12 is a partial sectional view of the protection assembly 80 corresponding to example 8. The protection assembly 80 comprises a valve port 81, a valve seat 82, a sealing gasket 83 inserted into the valve seat 82, and a protective ring 84 configured to protect the gasket 83. In this example, the protective ring 84 is riveted to the valve seat 82. The edge of the upper surface of the valve seat 82 comprises a riveting side 821. The riveting side 821 has an annular shape, and the protective ring 84 is riveted to the valve seat 82. The end portion of the protective ring 84 is preferably implemented in the same manner as the second protrusion of example 1. The second protrusion covers the vulnerable area of the gasket 83, thereby preventing damage to the gasket. In another aspect, the cross section of the second protrusion in the vertical direction is a rectangle that has a certain height, and, as in Example 7, a two-channel valve can be formed so that the second valve channel is formed thinner and longer to enhance the “ reduce the local differential pressure and the local flow rate "of the second valve channel.

In some cases, the end portion of the protective ring, i.e., the cross section of the second protrusion in the vertical direction, can also be a rectangular trapezium or a triangle.

In some cases, the top of the end portion of the protective ring in contact with the gasket may be made in the form of a rounded or beveled corner to protect the gasket from damage when the sealing gasket is pressed by the working edge.

Example 9

FIG. 13 is a partial sectional view of the protective assembly 90 for sealing the valve seat gasket corresponding to example 9. The protective assembly 90 comprises a valve channel 91, a valve seat 92, a sealing gasket 93 inserted into the valve seat 92, and a protective ring 94 configured to protect the gasket 93. The end portion of the protective ring is preferably implemented in the same way as the second protrusion of example 1. The second protrusion covers the vulnerable area of the gasket 93 in order to protect the seal body pad In this example, the protective ring 94 can be fixed to the valve seat with the fastener 95. FIG. 14 is a perspective view of the protective ring 94. A plurality of connecting holes 96 are formed in the protective ring 94. According to FIG. 13 and FIG. 14, a connecting hole corresponding to the protective ring is located on the valve seat 92. The protective ring is fixed to the valve seat with a fastener and a connecting hole. In one aspect, the end portion of the protective ring covers the vulnerable area of the gasket. In another aspect, the protective ring and the working edge can also form a second valve channel, allowing to change the local state of the fluid flow and reduce the local pressure drop and the local flow velocity, due to which the service life of the gasket can be significantly increased.

In some cases, the cross section of the end part of the protective ring in the vertical direction can also be a rectangular trapezoid or a triangle.

Preferably, the angle of the end portion of the protective ring in contact with the sealing gasket may be made in the form of a rounded or beveled angle.

For the protective assembly for the sealing gasket of the valve seat, corresponding to any of the above examples, the vulnerable area of the sealing gasket is located on the low pressure side of the medium, i.e. on the outlet side of the protective assembly for the sealing gasket of the valve seat. When the high-pressure medium passes from the inlet side, which has a relatively high pressure, to the outlet side, which has a relatively low pressure, the high-pressure medium quickly travels towards the low pressure side of the high pressure side and spreads explosively to the low pressure side. In this case, the metal material of the protective ring encloses the vulnerable area of the gasket, adequately protecting the gasket and preventing damage caused by an explosive high-speed, low-temperature gas jet.

For the protective assembly for sealing the valve seat gasket corresponding to any of the above examples, the cross section of the working edge of the valve channel of the protective assembly for the sealing gasket for the valve seat in the vertical direction can be a trapezoid. Preferably, the cross-section of the working edge in the vertical direction is a rectangular trapezoid. As shown in FIG. 15, the rectangular side of the working edge cross-section is the side that is near the first protrusion or the second protrusion of the protective ring. When the valve channel is closed, the working edge deepens into the sealing gasket, and the side of the working edge located near the vulnerable area is the rectangular side, so that when the valve channel is closed, friction between the working edge and the first lip or the second lip of the protective ring can be prevented . Preferably, the top of the working edge can be made in the form of a rounded or beveled corner, which avoids damage to the gasket.

Example 10

This utility model further comprises a pressure regulator. As shown in FIG. 16, the pressure regulator comprises a protective assembly for sealing a valve seat gasket according to any one of the above examples. Since the protective assembly for sealing the valve seat gasket corresponding to the present utility model can protect the sealing gasket of the protective unit from the high-pressure jet of the medium to prevent its destruction, the pressure regulator, in which the protective assembly for the sealing gasket of the valve seat is installed, can accordingly ensure a long service life of the sealing gaskets under conditions of operation with a large pressure drop.

It should be noted that in the above description, only preferred examples of the present utility model are presented, which are not intended to limit the scope of legal protection of the utility model. Any modification, equivalent replacement, improvement, etc., not departing from the essence and principle of this utility model, are within the scope of the legal protection of this utility model.

Claims (18)

1. A protective assembly for sealing a valve seat gasket comprising a valve channel and a valve seat, wherein the valve seat comprises a sealing gasket, and the sealing gasket contains a vulnerable area located on the outlet side of the valve channel, characterized in that the protective assembly further comprises a protective ring and the first valve cage, this protective ring partially covers the vulnerable area of the gasket, and the first valve cage is configured to fix the protective ring to near the valve. 2. Protective node under item 1, characterized in that the first protrusion is located on the first part of the protective ring, and the first part is located on the surface of the valve channel. 3. The security assembly according to claim 2, characterized in that the cross section of the first protrusion in the vertical direction is a trapezoid, a rectangle or a triangle. 4. Protective assembly according to claim 2, characterized in that the angle corresponding to the contacting part between the first protrusion and the sealing gasket, in the cross section of the first protrusion in the vertical direction is rounded or skewed. 5. Security node according to any one of paragraphs. 1-4, characterized in that the first valve cage fixes the protective ring on the valve seat using the second part of the protective ring. 6. The security assembly according to claim 5, wherein the cross section of the second part in the vertical direction is L-shaped or L-shaped, the second part containing the first end part in the vertical direction and the second end part in the horizontal direction, moreover the first end part is connected to the first part, and the second end part is in contact with the first valve cage or valve seat. 7. The security node of claim. 6, characterized in that the cross section of the second part in the vertical direction is L-shaped, the first groove is located on the contacting part between the first valve cell and the protective ring, and the second end part is inserted into the first groove; and the cross section of the second part in the vertical direction is L-shaped, the second groove is located on the contacting part between the valve seat and the second part, and the second end part is inserted into the second groove. 8. Protective node under item 1, characterized in that protective ring combined with the valve seat; or the protective assembly comprises a second valve cage, and a protective ring integrated with the second valve cage. 9. Protective assembly according to claim. 1, characterized in that the protective ring of the protector assembly is fixed to the valve seat with a fastener. 10. Protective assembly according to claim. 8 or 9, characterized in that the protective ring is made with a second protrusion and is located on the surface of the valve seat. 11. The security assembly of claim 10, wherein the cross section of the second protrusion in the vertical direction is a trapezoid, a rectangle or a triangle. 12. Protective knot under item 11, characterized in that the angle corresponding to the contiguous part between the second protrusion and the sealing gasket, in cross-section is rounded or beveled. 13. Security node according to any one of paragraphs. 1-4, characterized in that the valve channel contains a working edge, and the cross-section of the working edge in the vertical direction is a rectangular trapezium, and the rectangular side of this rectangular trapezoid is located on the side of the vulnerable area. 14. Pressure regulator, characterized in that it contains a protective node for sealing the valve seat according to any one of paragraphs. 1-13.

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