RU2151337C1 - Excessive-pressure valve - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: valve is used for automatic maintenance of preset gage pressure (backup pressure) and for emergency shutoff of gas pipeline channel. Valve has body with coaxial working branch pipes and with internal cavity. It accommodates spring-loaded shutoff member mounted on guide supporting element for displacement to oppose spring force. Shutoff member has thrust surface for spring. Internal space of body is divided by transverse partition with through axial hole. Guide supporting element is rigidly secured in body. H-shaped shutoff member has blind central hole. The latter contains guide supporting element with damping chamber formed between mentioned hole and hole bottom. Operating surfaces of shutoff member are positioned on different sides of partition so that axial hole of partition may be overlapped. Valve makes it possible to shut off gas pipeline and to stop gas flow within certain minimum permissible time. EFFECT: higher efficiency. 2 cl, 1 dwg

Description

 The overpressure valve is designed to automatically maintain a constant predetermined overpressure (back-up) in a room or structure, to ensure that air flows from one room to another in only one direction, and for emergency blocking of the gas channel with a sharp increase in pressure above a certain threshold value in the working room or outside his.

 Known tripping device reverse action. However, due to the fact that the centering of the locking member, which is made in the form of a glass, occurs along the outer surface of the locking member in contact with the inner surface of the housing, this leads to a decrease in the living section; increased wear of working surfaces requires the manufacture of a locking member from wear-resistant materials; during sharp changes of significant pressure, a strong blow of the locking body on the saddle occurs, which can lead to deformation of the working elements; the lack of sealing elements does not allow to ensure complete tightness of the closed valve / USSR Copyright Certificate SU 1272048 Al F 16 K 17/02, 1985, BI N 43, 11.23.86./.

 Known safety valve for controlling excess flow, consisting of a housing with inlet and outlet openings, a chamber with a valve and valve seats, which are located on the same longitudinal axis. A disk-like valve with two smaller cylindrical guide surfaces is supported in the chamber by two coil springs, the outer ends of which abut against annular ledges located on the inner surface of the housing. The springs control the movement of the valve, which, when pressed, resists the movement of the valve under the action of the normal flow force acting on the surface of the valve. In case of excessive flow, the valve closes the inlet.

 This is a known device - the safety valve has several disadvantages: the springs are in the flow of the working medium, this leads to an increase in hydraulic resistance; with sharp changes of significant pressure, a strong impact of the locking element against the seat occurs, which can lead to deformation of the working elements, the suspension system of the axis of the locking element does not accurately center the locking element relative to the inner surface of the housing / US Patent N 3561471 F 16 K 17/24, 1971./. This device is taken as a prototype.

 The technical task to be solved is the development of a valve that allows shutting off the gas pipeline and stopping the gas flow for some minimum permissible time when the gas flowing through the gas pipeline is exposed to a shock wave, a compression wave with excess pressure and a duration exceeding a certain threshold value. The device under development should have the required speed, strength, the ability to return to its original position, and for hazardous industries, storage facilities, nuclear power plants, in which an accident may result in the release of radioactive or toxic substances, the ability to keep the shut-off element for a long time in a closed state.

 The specified technical problem is solved by an overpressure valve containing a housing with coaxial working nozzles with an internal cavity, in which a spring-loaded locking element is mounted, mounted on a guide supporting element with the ability to move against the spring force and having a contact surface for the spring, characterized in that the internal cavity of the housing divided by a transverse partition with a through axial hole, the guide support element is rigidly fixed in the housing, the locking element has an H-shaped mu with a hollow central bore for receiving the guide support member to form a damping chamber between it and the bottom of the hole, the working surfaces of the blocking member placed on either side of the partition to overlap its axial hole.

Distinctive features of the prototype are:
- separation of the internal cavity of the housing by a transverse partition with a through axial hole;
- rigid fastening of the guide support element in the housing;
- implementation of the locking element H-shaped with a blind central hole;
- placement in the blind central hole of the guide support element with the formation of a damping chamber between the specified element and the bottom of the hole;
- implementation of the locking element in such a way that its working surfaces are placed on opposite sides of the partition with possible overlapping of its axial hole;
- installation of the air filter from the side of the direct air pipe.

 The use of the body partition, the rigid fastening of the support element, the use of the cavity between the guide support element and the locking element, which provides damping of the impact of the locking element along the transverse partition of the housing, reduces the mass of the locking element, which leads to a higher sensitivity of the valve to changes in overpressure on its surfaces.

 The use of an H-shaped locking element with overlapping the working surface on different sides of the partition, rigid fixing of the guide element allows you to remove the spring from the air stream and block the gas channel when the shock element is exposed to a shock wave of either one or the other direction with excess pressure and a duration of more some threshold value.

 The use of an air filter allows you to protect the locking element from large foreign elements.

 The drawing shows the inventive device for emergency shutdown of the gas pipeline in the context. The arrows indicate the direction of gas flow. The inventive device comprises a housing 1, separated inside by a partition 2 with an axial hole, a locking element 3, which has the ability to move along the guide support element, rigidly fixed in the housing 1 (for example, along the axis 4, which is rigidly fixed in the housing 1 by a nut 5), and pressed against the shock-absorbing element 6 located on the partition wall 2 of the housing 1, by the spring 7. The second shock-absorbing element 8 is located on the opposite side of the partition wall 2 of the housing 1. The locking element 3 has an H-shape with a dull central Verstov for accommodating the axle 4. Between the axis 4 and the locking element 3 is arranged a damping chamber A. On the side of the receiving sleeve is mounted an air filter 9.

 The device operates as follows.

 If the room’s overpressure is less than a certain predetermined value p, the right part of the shut-off element 3 overlaps the cross section of the gas pipeline due to the spring force 7 adhering to the partition 2 of the housing 1.

 When the excess pressure of p is exceeded, the right side of the valve moves away from the partition 2 and air flows into the resulting slit of the device.

 In the event that an accident occurs in a room with excess pressure, accompanied by a shock wave or a sharp increase in pressure above a certain threshold value, from their impact on the shut-off element 3, its left part, moving to the right, overlaps the cross section of the gas pipeline 4. In this case, an additional latching device is triggered (not shown), and the room with overpressure will be hermetically sealed for a long time.

 Any device known for fixing the position of the locking element 3 can be installed in the collision region of the locking element 3 and the partition 2, or on the inner surface of the housing 1, or on the nut 5, or on the central axis 4. The introduction of such proposed elements helps to solve the problem.

 In a stationary gas flow, the force due to the high-speed pressure of the gas flow around the shut-off element 3 is compensated by the spring-loaded force of the spring 7 on the shut-off element 3, while the shut-off element 3 is held in a certain position relative to the partition 2. If the shut-off element 3 is in the middle position relative to the partition 2 due to the pressure head of the gas flow of a certain size, an attempt to increase the flow rate will lead to an increase in flow resistance by reducing the flow sections.

 With a sharp increase in pressure in the gas stream caused by an air shock wave or compression wave, the locking element 3 begins to move along the central axis of the gas pipeline 4. At the same time, the flow (live) section between the locking element 3 and the partition 2 decreases until the gas channel is completely blocked. The shock of the locking element 3 against the partition 2 is mitigated by the shock-absorbing elements 8 fixed to the surface of the partition 2. and the damping chamber A. After compression of the shock-absorbing elements, the position of the locking element 3 can be fixed by any known element. In the case when it is not necessary to return the locking element 3 to its original position, for example, when the gas pipeline is shut off once, the locking element 3 can be stopped and fixed by jamming it in the conical hole of the nut 5, due to the deformation of the locking element 3, which is ensured the shape of the locking element 3. In the absence of a locking element, after reducing the pressure in the gas stream below a critical value, under the influence of a spring 7, the locking element 3 returns to its original position e. In the event of an air-blast coming from the opposite side (due to an external explosion), the shut-off element moves and closes the gas pipeline channel in a similar way, preventing the air-blast from passing into the working room.

The device can be implemented in the following version: inlet diameter - 50 mm; the locking element is made of steel; the mass of the locking element is 50 g; full stroke of the locking element - 8.8 mm; air volumetric flow rate - 12.5 dm ³ / s; when exposed to an air HC with an overpressure of 5 atm and 0.5 atm, the channel overlap time is ≈300 μs and 3 ms, respectively, while the air leak is ≈500 cm ³ .

 Thus, the technical feasibility and effectiveness of the proposed device.

Claims (2)

 1. An overpressure valve comprising a housing with coaxial working nozzles with an internal cavity, in which a spring-loaded locking element is mounted, mounted on a guide support element with the ability to move against the spring force and having a thrust surface for the spring, characterized in that the internal cavity of the housing is divided by a transverse a partition with a through axial hole, the guide support element is rigidly fixed in the housing, the locking element has an H-shape with a blind central hole for placing in it a guide support element with the formation of a damping chamber between it and the bottom of the hole, the working surfaces of the locking body are placed on different sides of the partition with the possibility of overlapping its axial holes.  2. The overpressure valve according to claim 1, characterized in that it is equipped with an air filter on the inlet side.