RU2634999C1 - Safety valve - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: safety valve comprises a housing with inlet and outlet nozzles, a bellows sealed to housing and movable member, a locking mechanism comprising a spring loaded separator with cylindrical retainers. Fixing mechanism is provided with an additional spring 10, disposed in internal cavity of movable member 11 in the form of a cup, interacting with cylindrical locks 8, and support 14 with a rod 15 provided with a head 16, connected to the sealing assembly, consisting of a slide valve 5 having an internal groove, and a sealing seat 6 on the outlet nozzle 3. The head has 16 rod 15 in the groove of slide valve 5.

EFFECT: expansion of operational capabilities of safety valve and increasing the reliability of its operation during exploitation due to the imperviousness of shutter after multiple responses.

6 cl, 2 dwg

Description

The invention relates to valve engineering, is intended for use as a safety valve of periodic action, allowing multiple operations, and can be used in nuclear energy, chemical industry, energy complex.

Safety valves are known, which include a housing with inlet and outlet nozzles, a spool, a bellows seal and a spring mechanism for creating a load (see, for example, Kashansky M.S., Stepanov V.V., Goldfayn V.N. and others. Ship fittings. - L.: Shipbuilding, 1975, Fig. 202, p. 300; Gurevich D.F., Shiryaev V.V. et al. Armature of nuclear power plants. - M .: Atomizdat, 1978, Fig. 5.3, p. 117).

In these valves, the medium is supplied in the direction “to the spool”, and a spring-loaded bellows is used as a sensing element.

With increased effective bellows area, these valves operate as full bore.

The nature of the expiration of the working medium in such structures at the initial opening phase is the throttling of the medium through the gap formed. In the second phase of the opening, a sharper rise of the spool occurs, increasing the flow rate of the medium through the valve.

The disadvantage of these valves is the lack of tightness in the valve, especially after the valve is activated. Emerging leakage through the shutter, in turn, leads to erosion of the sealing surfaces and a further increase in leakage in the shutter.

Closest to the proposed valve design is a safety valve (see ed. St. SU No. 1489276 A1, F16K 17/14, 1987), which consists of a housing with inlet and outlet nozzles, a bellows transmitting the force of the medium to be protected to a sealing element made in the form of a discontinuous rod with a head, a movable support in the form of a spring-loaded ring separator, in which cylindrical clamps with radial ends are mounted with inclined ends contacting from the outside with the housing bore and with the inside the front side - with a movable element. This valve provides complete tightness on the sealing element prior to actuation and high accuracy of actuation due to the locking mechanism.

According to the largest number of common features and the problem to be solved, we select the valve for the prototype according to the copyright certificate No. 1489276.

The disadvantage of this valve is that the valve is restored only after replacing the sealing element with a new one, therefore this design relates to single-use devices.

The technical task of the proposed technical solution is to create a safety valve that provides tightness on the seal assembly after repeated trips.

The solution of the technical problem will expand the functionality of the safety valve.

The problem is solved due to the fact that the locking mechanism is equipped with an additional spring located in the inner cavity of the movable element, made in the form of a cup interacting with cylindrical clamps, and supports with a rod equipped with a head and connected to the seal assembly, consisting of a spool having an internal the groove, and the sealing seat on the outlet pipe, and the rod head is placed in the groove of the spool and installed relative to the upper end of the groove with axial clearance, the value of orogo exceeds the stroke locking mechanism.

The surface of the rod head in contact with the lower end of the spool groove is spherical, and a spring is installed above the head with a stroke greater than the axial clearance.

The lower end of the glass of the movable element is provided with a guide shell interacting with the support associated with the bellows.

The additional spring is equipped with a spring force adjusting unit.

The essence of the technical solution is illustrated by drawings.

In FIG. 1 shows a general view of the safety valve.

In FIG. 2 shows a valve operation diagram.

The safety valve consists of a housing 1 with input 2 and output 3 nozzles. In the internal cavity of the housing 1 there is a bellows 4, a sealing assembly including a spool 5 interacting with a sealing seat 6 of the outlet pipe 3, a locking mechanism consisting of a separator 7 with cylindrical clips 8, a main spring 9 and an additional spring 10 interacting with the movable element 11 and placed in its inner cavity. The compression force of the additional spring 10 is provided by the unit for adjusting the compression force of the spring. The movable element 11 is made in the form of a glass 12, interacting with the upper end with cylindrical clamps 8, and the lower end due to the guide shell 13 with the support 14 and the rod 15 provided with a head 16.

The tightness of the internal cavity relative to the external environment is ensured by a bellows 4, which is connected to the support 14 from one end and to the housing 1 from the other, and is simultaneously designed to transmit forces from the pressure of the working medium through the cup 12 to the locking mechanism, and through the stem 15 to the spool 5.

The head 16 of the rod 15 is located in the groove 17, made in the spool 5, and is installed relative to the upper end of the groove 17 with an axial clearance 18, the value of which exceeds the working stroke 19 of the locking mechanism. The surface of the head 16 in contact with the lower end of the groove 17 is made spherical to ensure self-alignment of the spool 5 relative to the sealing seat 6 of the outlet pipe 3.

Above the head 16, a spring 20 is installed, designed to compress the spool 5 to the stem 15 after the valve is actuated and has a stroke greater than the axial clearance 18.

The adjustment unit of the compression force of the additional spring 10 consists of a support sleeve 21, a screw 22 and a flange 23.

The valve is as follows.

In the initial state, the spool 5 is in the “closed” position and pressed against the sealing seat 6 with the required design force. The force for the seal assembly is created by the total force of two springs: the main 9 and additional 10, as well as the pressure of the working medium on the spool 5.

The locking mechanism is in the lower working position: the cylindrical latches 8 under the action of the force generated by the spring 9 and transmitted through the separator 7 are pressed against the glass 12.

The additional spring 10 creates an additional force that allows you to increase the load on the spool 5 in the "closed" position, thereby contributing to an increase in the tightness of the seal assembly.

At the working pressure of the medium in the protected system, the force from the action of the pressure of the medium on the effective area of the bellows 4 does not exceed the combined force of the preliminary preload of the main 9 and additional 10 springs, as well as the force from the pressure of the medium on the spool 5.

At the same time, the valve is sealed in the seal assembly: the sealing band of the slide valve 5 - the sealing seat 6 of the outlet pipe 3.

With increasing pressure of the medium in the protected system in the cavity above the spool 5, the force from the action of the pressure of the medium on the effective area of the bellows 4 begins to exceed the value of the total force of the preliminary preload of the main 9 and an additional 10 springs.

In this case, the rod 15 together with the support 14 and the bellows 4 begins to move relative to the remaining stationary spool 5.

When the protected medium reaches the valve operating pressure, the separator 7 moves together with the cylindrical clamps 8.

Under the action of the force transmitted by the glass 12, the clamps 8 will move in the radial direction.

After the radial movement of the clamps 8, the cup 12 is released from the force created by the main spring 9. The force developed by the bellows 4 is completely transmitted to the support 14 and the cup 12 is moved, compressing the inner spring 10.

In this case, the rod 15 moves up and raises the spool 5 above the seat 6 of the outlet pipe 3 by the valve stroke value, passing the working medium of the protected system through an open passage section.

When the pressure in the protected system is reduced to the pressure of the reverse seating Rop, the spool 5 moves towards the closing direction by moving the cup 12, the clamps 8 are released, and the force from the main 9 and additional 10 springs is transmitted through the stem 15 to the spool 5, which moves all the way to the sealing seat 6 of the outlet pipe 3, closing the passage section of the valve.

The passage of the medium to be protected through the valve seal assembly is stopped.

The operation of the proposed safety valve is illustrated by the principle diagram shown in FIG. 2.

The following notation is used in the diagram:

P is the pressure of the medium;

h is the stroke of the valve stem;

Rr - working pressure;

Rpo - pressure of full opening;

Rop - pressure back landing;

hotkr - stroke of the valve opening valve;

hf is the stroke of the rod after opening the valve until it locks.

Point 1 in the diagram corresponds to the beginning of the movement of the rod 15 in the direction of opening the valve and the beginning of compression of the main 9 and additional 10 springs with increasing pressure in the system to the opening pressure.

Section 1-2 corresponds to a rise in the pressure of the medium until the cup 12 is unlocked and the rod 15 moves within its idle speed (with the spool 5 stationary and maintaining tightness in the seal assembly).

Point 2 corresponds to the moment the stem is released, the main spring 9 releases the force after compressing both springs 9 and 10 within the idle stroke of the rod 15 (with the spool 5 stationary and maintaining tightness in the seal assembly) and the beginning of the sharp rise of the spool 5.

Section 2-3 corresponds to the full stroke of the rod 15 and the opening of the valve through passage.

Section 3-4 corresponds to a decrease in the pressure of the medium in front of the valve to the pressure at which the rod 15 is fixed under the action of an additional 10 spring and the rod 15 is suddenly loaded by the force of the main 9 spring.

Section 4-5 corresponds to the quick closing of the valve, ensuring tightness along the seal assembly.

Section 5-1 corresponds to an increase in the pressure of the medium up to the working pressure in the system after the valve is activated.

The proposed design of the safety valve allows you to provide a high degree of tightness of the shutter at a working pressure of the medium due to the joint creation of a load on it from the main and additional springs, valve actuation at a pressure of the medium equal to the pressure of full opening with the release of the locking mechanism and the shutter returns to its original position "closed" after reducing the pressure of the working medium in the protected system to the pressure of the return landing with restoring the required degree of tightness of the sealing unit nenia.

Thus, the invention allows to expand the operational capabilities of the safety valve and increase the reliability of operation during operation by ensuring the tightness of the seal assembly after repeated operations.

Claims (6)

1. A safety valve comprising a housing with inlet and outlet nozzles, a bellows hermetically connected to the housing and a movable element associated with the seal assembly, a locking mechanism comprising a spring-loaded separator with cylindrical latches, characterized in that the locking mechanism is provided with an additional spring placed in the inner cavity of the movable element, made in the form of a glass, interacting with cylindrical clamps, and supports with a rod equipped with a head and associated with the node seal consisting of a spool having an internal bore, and the sealing seat on the outlet pipe, the head is placed in the groove of the spool. 2. The safety valve according to claim 1, characterized in that the rod head is mounted relative to the upper end of the spool groove with an axial clearance, the magnitude of which is greater than the working stroke of the locking mechanism. 3. The safety valve according to claim 1, characterized in that a spring is installed above the stem head having a stroke greater than the axial clearance. 4. The safety valve according to claim 1, characterized in that the surface of the head in contact with the lower end of the groove of the spool is made spherical. 5. The safety valve according to claim 1, characterized in that the lower end of the glass of the movable element is provided with a guide shell interacting with a support associated with the bellows. 6. The safety valve according to claim 1, characterized in that the additional spring is provided with a compression force setting unit.

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