RU2447346C1 - Stop valve with unloaded stop - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: stop valve with an unloaded stop comprises lower and upper casings, a seat with a sealing surface, a plunger in the form of a hollow bushing with a sealing surface and through holes made in its bottom to create a plunger unloading chamber, a drive stem, a membrane bellow with folding shape of corrugations having end parts, the upper of which is tightly connected to the upper part of the plunger, and the lower one is tightly installed into the valve casing, providing for axial displacement of the plunger by the drive force during bellow compression. The inner cavity of the bellow via a channel made on the lower end part is communicated via a bypass line equipped with a stop device, with the working fluid pressure cavity "under the stop". The upper end part of the bellow is made so that it forms a plunger pair with the upper casing and a cavity between the upper casing and the external surface of the bellow. The average diameter of the bellow is made as equal to the average diameter of the sealing surface of the valve stop. The valve is equipped with the second bypass line with a stop device, providing for connection of the working fluid pressure cavity "onto the stop" with the external cavity of the bellow. Both channels of bypass lines are equipped with a check valve. Stop devices are made as normally open.

EFFECT: expansion of functional capabilities of a valve with an unloaded stop providing for its operation in case of double-sided direction of a working fluid flow.

3 cl, 1 dwg

Description

The invention relates to mechanical engineering, and in particular to shut-off valves with an unloading lock used in industrial pipe fittings, and can be used to shut off the working fluids of liquids and gases with high pressure and high temperature with a two-way flow direction of the working medium, mainly in the nuclear industry.

Known designs of valves for high parameters of the working environment with a two-way flow direction (see. "Armature of nuclear power plants." DF Gurevich and other Atomizdat, 1978, Fig. 3.23, 4.3). These valve designs have drawbacks: large overall dimensions and weight of valves, high shock loads on valve sealing surfaces, which reduces valve tightness and service life, low throughput and valve response speed.

There are known designs of a shut-off and shut-off and control valve with an unloading plunger (see "Regulating devices and automatic control devices" of the company "Rust", Moscow, 2009, Fig. 12, 13), whose valves have an unloaded plunger with holes in the upper part plungers, which almost completely unload the plunger from the differential pressure in the upper and lower chamber of the cylinder. Only the area of the rod is not unloaded from the action of the working medium, and since it is insignificant, the valve drive force is significantly reduced. The design has plunger seals, which are made mainly of rubber and polymer. They provide the necessary tightness of the shutter and prevent leakage of the working medium in the gap between the sleeve and the plunger, reducing mechanical impurities entering the gap. This valve design works well in clean working environments, but in contaminated environments seals are prone to contamination, while increasing axial force to move the plunger and possibly stopping it. Another significant drawback is the limited temperature range (from - 100 ° C to 230 ° C), within which the sealing materials of radial seals work satisfactorily.

It is very difficult to obtain a tight shutoff of the fluid flow in the closed position of the valve, since the tightness of the valve shutter is determined by both the main seal of the shutter-plunger and the radial seals of the plunger.

In the known valve design with an unloaded gate with a pilot valve (see Fig. 14), the plunger unloading chamber is connected to the outlet pipe through an auxiliary seat, which is closed in the closed state by a spring-loaded pilot valve. By eliminating the tight connection between the primary and secondary seats of the throttle assembly, leakage in the closed state of the valve can be significantly reduced. The radial seals of the plunger can be replaced with metal piston rings, thereby increasing the temperature range of the structure.

The most important drawbacks of this design are the clogging of the radial seal even with slightly contaminated working media and its operation only when the working medium is supplied to the “shutter”. In the event of a reverse differential pressure, the pilot valve of the valve will open. With small gate openings, when the stroke of the plunger is comparable to the stroke of the pilot valve, unstable operation of the throttle assembly is possible, especially at large pressure drops.

The pilot-operated unloaded valve is currently the only design that allows you to adjust the working environment with a large pressure drop with a low drive force and block the flow area of large DN and large PN in a short period of time. However, it is not possible to use this design to close the shutter with a two-way flow direction of the working medium. Pipelines of power plants, especially nuclear ones, require two-way shutoff of the working medium flow in a short period of time. Cutting off the pipe cross section for high pressure and high DN for a short period of time without unloading the valve is always problematic.

It is for this reason that shut-off valves with two-way direction are forced to do without unloading the shutter, using powerful actuators, which, on the one hand, provide short closing times, and on the other hand, provide significant dynamic forces on the seats at the end of closing. Due to the impact of the shutter on the sealing surface of the seat, the shutter is not sealed.

The closest technical solution is the solution for a patent of the Russian Federation for utility model No. 56532. This valve has the largest number of similar essential features and has the same significant drawback as the previously mentioned analogues, that is, it is impossible to use this design to close the shutter in case of a change in the direction of the flow of the working medium.

This valve contains the following similar essential features:

case, seat with a sealing surface, a plunger, in the form of a hollow sleeve with a sealing surface and through holes made in its bottom, with the formation of a plunger unloading chamber, a drive stem, a membrane bellows with a folding corrugation shape with end parts, the upper of which is hermetically connected to the upper part of the plunger, and the lower one is hermetically installed in the valve body, providing axial movement of the plunger while compressing the bellows from the drive force, the internal cavity of the bellows through a channel made on the bottom end parts, communicated through a bypass line equipped with a locking device, with a pressure cavity of the working medium "under the shutter".

The disadvantage of this valve having an unloaded shutter is the impossibility of its operation in the event of a change in the direction of flow of the working medium.

The problem solved by the invention is to expand the functionality of the valve with an unloaded valve, operating at high pressures, and large flow cross sections, namely the achievement of the possibility of its operation in the event of a change in the direction of flow of the working medium.

The essence of solving the technical problem lies in the fact that the upper end part of the bellows is made in such a way that forms a plunger pair and a cavity between the upper body and the outer surface of the bellows, the average diameter of which is equal to the average diameter of the sealing surface of the valve shutter, the valve is equipped with a second bypass a line with a shut-off device, providing a connection of the pressure medium’s “on the shutter” pressure cavity with the external bellows cavity, in addition, both channels of the bypass lines equipped with a check valve, while the locking device is made normally open action.

It is possible that piston rings are installed between the upper end part of the bellows and the upper valve body.

It is possible that piston rings are installed between the lower end of the bellows and the valve plug.

In FIG. presents a longitudinal section of a General view of the valve in the open position.

The valve comprises a seat 1 with a sealing surface located in the valve body 2, a plunger 3, made in the form of a hollow sleeve with through holes 4. A metal welded bellows 5 is hermetically connected to the end parts 6, 7. The upper end part 6 is hermetically connected to the upper part of the plunger 3, and the lower part 7 is hermetically seated between the upper body 8 and the flange of the valve body 2. The internal cavity of the bellows B through the channel made in the end part 7 and the nozzle 9, communicated through the check valve 10, the bypass line and the nozzle 11 with the cavity of the working medium And "under the shutter". The bypass line contains a locking device 12 normally open action (BUT). The plunger 3, hermetically connected to the end piece 6, is equipped with o-rings 13, 14, which provide relative tightness of the cavities of the bellows B and C. Cavity B through the channel in the end part 7 and the fitting 17, the check valve 18 is connected to the bypass line through the shut-off device 16 normally open action, and the fitting 15 is connected to the cavity G.

The movement of the plunger 3 is carried out by the drive through the rod 19, which is sealed relative to the external environment by a bellows 20, made in accordance with GOST 21744-85. The shut-off valve with an unloaded shutter allows the actuator to be used with little force to move. In this regard, the stem is made of small cross-section, even for fittings of large DN and PN. The small stem diameter allows the use of multi-layer bellows for high pressures up to 25 MPa.

This is another of the advantages of the proposed valve in terms of increasing its tightness relative to the external environment.

The valve operates as follows.

In the open position, when the flow of the working medium moves from the cavity A to the cavity G of the housing 2, the working medium passes through the through holes 4 to the upper part of the plunger 3, then it fills the cavity B through the end gap of the piston rings 14. At the same time, the working medium rushes under the same pressure through the fitting 11, the shut-off device normally open action (HO) 12, the check valve 10, the fitting 9 and the channels of the lower end part 7 into the cavity B.

Plunger 3 is unloaded. When moving the plunger down, the valve shutter closes, at the same time the bellows 5 is compressed and the bellows 20 is expanded by the valve stroke. The sealing surface of the plunger 3 rests on the sealing surface of the seat of the housing 1, while the bellows 5 is almost completely compressed. Between the corrugations there are mini-gaps of 0.03-0.04 mm. When the valve is operating, the check valve 18 closes from the differential pressure and cuts off the flow of the working medium through the fitting 15 into the cavity G.

The drive force through the rod 19 provides the plunger 3 overlapping the flow of the working medium and sealing the sealing surfaces of the shutter. Then a command is issued to close the locking devices 12, 16, which disrupt the unloading of the bellows 5 and prevent leakage of the working medium into the cavity G. Moreover, when the bellows 5 is almost completely compressed, it turns into a rigid corrugated sleeve that can withstand very high external or internal pressure of the working environment.

If the flow of the working medium changes its direction in the open position and moves from the cavity G to the cavity A of the housing 2, the working medium fills the cavity under the plunger 3, through the end gap of the piston rings 13, fills the cavity B and at the same time rushes through the fitting 15, the open shut-off the device 16, the check valve 18, the fitting 17 and the channels of the lower end part 7 into the cavity B. The check valve 10 closes. Plunger 3 is unloaded, after which it may move to close.

When the valve is opened, a command is issued to open the locking devices 12, 16, after which the check valve 10 or 18 opens, depending on the direction of the working medium. The working medium fills the cavity B, C, while unloading the bellows 5, and the plunger in the unloaded state is ready for operation.

It should be noted that to prevent rupture of the bellows 5 from the difference in excess external or internal pressure, only locking devices 12, 16 of normally open action (BUT) can be used, that is, even in the absence of drive power, the locking devices will be in the open position and the bellows 5 will be unloaded.

The proposed original solution was implemented on a prototype at the applicant’s enterprise and can be widely used as a shut-off element, a shut-off shut-off element with placement in the passage, angular structures of the bodies and in the axial flow valve body.

These features distinguish the technical solution from the prototype and determine the compliance of this solution with the requirements of the invention.

Claims (3)

1. Shut-off valve with an unloaded shutter, comprising a lower and upper body, a seat with a sealing surface, a plunger in the form of a hollow sleeve with a sealing surface and through holes made in its bottom, with the formation of a chamber for unloading the plunger, the actuator stem, a membrane bellows with a folding shape corrugation with end parts, the upper of which is hermetically connected to the upper part of the plunger, and the lower is hermetically mounted in the valve body, providing axial movement of the bellows from the drive force unzhera, the inner cavity of the bellows through a channel made on the lower end part, communicated through a bypass line equipped with a locking device, with a pressure cavity of the working medium "under the shutter", characterized in that the upper end part of the bellows is made in such a way that it forms with the upper case a plunger pair and a cavity between the upper body and the outer surface of the bellows, the average diameter of which is equal to the average diameter of the sealing surface of the valve shutter, the valve is equipped with a second bypass line minutes with a locking device providing a connection cavity pressure working medium "the gate" with the outer cavity of the bellows, in addition, both channels are bypass lines are provided with a check valve, wherein the locking devices are made of a normally open action. 2. The shut-off valve according to claim 1, characterized in that piston rings are installed between the upper end part of the bellows and the upper valve body. 3. The shut-off valve according to claim 1, characterized in that piston rings are installed between the lower end part of the bellows and the valve plug.