RU74183U1 - THERMAL VALVE (OPTIONS) - Google Patents

Abstract

The utility model relates to domestic and industrial gas supply systems and can be used to stop gas supply in emergency situations, for example, in case of fire. The thermal shut-off valve according to the first embodiment contains a hollow body in which a shut-off mechanism is mounted, made in the form of an axially spring-loaded relative to the housing of the locking element having the ability to interact with the landing surface of the housing when the gas supply is shut off. The valve is equipped with a support fixed in the housing, the locking element is spring-loaded relative to the support, and the valve is additionally equipped with a latch and rods installed on the support, covering the spring and the locking element fixed from the axial movement by rods and a latch mounted on them, made in the form of a split ring, the ends which is connected by a fusible element. The thermal shut-off valve according to the second variant is characterized by the presence of a stop instead of tie rods with elastic petals pulled together by a latch, and the locking element abuts upora.2 pitch p with n-ly, 4 Fig.

Description

The utility model relates to domestic and industrial gas supply systems and can be used to stop gas supply in emergency situations, for example, in case of fire.

Known thermal shutoff valve containing a hollow body with flanges at its ends with holes on them for fasteners. A locking mechanism for shutting off the gas supply is installed in the housing, mounted on a support provided in the housing and made in the form of a plate fixed to the rod with a locking surface (locking element) that can interact when the gas supply is shut off with the landing surface of the housing. A groove having a conical shape is made on the surface of the stem, in which the locking element (ball) is partially placed in the open position of the valve. In the opening of the support, the fusible insert and the sleeve are located end to end to each other, in the holes of which the rod is placed with the possibility of axial movement. In the sleeve there is a radial hole in which a locking element is partially placed, having the possibility of entering the groove made in the support in the closed position of the valve. On the surface of the rod there is a groove for the outflow of molten material of the fusible insert.

In the initial position, the thermal shutoff valve is in the open position. The elastic element is compressed and its force is compensated by the locking element. The plate does not overlap the body cavity. In an emergency, for example, in the event of a fire, due to the temperature increase, the fuse-link melts, as a result of which the rod begins to move under the action of the elastic element, bringing the plate closer to the landing hole. As soon as the locking element occupies a position opposite the groove made in the support, the locking element is extruded partially into the groove by the conical surface of the rod groove, thereby releasing the rod, which under

the action of the elastic element moves sharply until the locking surface of the plate does not sit on the landing surface of the housing, which leads to blocking the gas supply.

(see RF patent for utility model No. 61834, class F16K 17/40, 2006) is the closest analogue.

As a result of the analysis of the implementation of the known thermal shut-off valve, it should be noted that this valve is characterized by significant axial and radial dimensions, which is due to the location of the plate and the valve locking mechanism in the open position, it is inconvenient when mounted in a gas supply line, especially in a line that is already is in operation, since the installation of the housing between the flanges of the gas line requires free space, which leads to the need to cut part of the pipe and fasten to second flange. In addition, the valve is very complex structurally, as it contains a large number of structural elements, some of which have a rather complex shape and are very labor-intensive in manufacturing.

The objective of this utility model is to develop a thermal shut-off valve that is structurally simple, containing a minimum number of elements that are simple to manufacture and also having small dimensions, which makes it easy to mount it in the gas supply system, including in crowded places.

The task is ensured by the fact that in a thermal shut-off valve containing a hollow body, in which a locking mechanism is mounted, made in the form of an axially spring-loaded locking element relative to the housing, having the ability to interact with the housing seating surface when the gas supply is shut off, it is new that the valve equipped with a support fixed in the housing, the locking element is spring-loaded relative to the support, and the valve is additionally equipped with a latch and rods mounted on the support, o vatyvayuschimi spring and a locking element fixed against axial displacement rods and

a latch mounted on them, made in the form of a split ring, the ends of which are connected by a fusible element.

The thermal shut-off valve according to the second embodiment is characterized in that it is equipped with a latch, an abutment with elastic petals, a support fixed in the housing, the locking element is spring-loaded relative to the support and rests on the lobes of the abutment fixed in the housing, which are pulled together by a retainer made in the form of a split ring, the ends of which are connected fusible element.

When conducting patent research, the prior art did not reveal solutions that are identical to the declared one, and therefore, the claimed utility model meets the eligibility condition “novelty”.

We believe that the information presented in the application materials is sufficient for the practical implementation of the utility model.

The application materials disclose the design of two thermal shutoff valves related to devices of the same type, of the same purpose and providing, when used, the same technical result, that is, variants.

The essence of the utility model is illustrated by graphic materials on which:

figure 1 - thermal shut-off valve, option 1, axial section;

figure 2 - locking mechanism of the thermal shut-off valve according to option 1;

figure 3 - thermal shut-off valve, option 2, axial section;

figure 4 - locking mechanism of the thermal shut-off valve, according to option 2.

The thermal shut-off valve (option 1) is made in the form of a hollow body 1, with elements 2 and 3 for its installation in the gas supply system. In the case there is a landing surface (girdle) "A", for example, conical in shape. In the housing 1 there is a locking mechanism for shutting off the gas supply.

The locking mechanism is made in the form of a support 4. The support 4 is fixed in the cavity of the housing by means of its protrusions placed in a groove (groove) made in the cavity of the housing. The locking mechanism contains a locking element 5, which can be made in the form of a ball, spherical, conical or

a different body shape. In principle, its shape may be different, it is important that this shape allows, when in contact with surface "A", to reliably shut off the gas supply. The locking element 5 is spring-loaded relative to the support by an elastic element (spring) 6 in the direction of the surface "A". To hold the locking mechanism in the "open" position, in which the spring 6 is compressed, and the locking element 5 is not in contact with the surface "A", but it is affected by the compression force of the spring, directed towards the surface "A", rods 7 are used that cover the spring and locking element. Rod 7 at one end mounted on the support 4 with the possibility of rotation relative to it. The clamp ends 8 are put on other ends of the rods, located on the other side relative to the spring 6 with respect to the locking element 5 and made, for example, in the form of a split ring, the ends of which are connected (soldered) by fusible material 9. The ring holds the locking element of the locking mechanism in the cocked ( open) position. As a fusible material, the Byda alloy can be used.

Assembling a thermal shutoff valve in this embodiment is very simple. Initially, the locking mechanism is assembled. A thrust ring is hooked onto a split ring welded by a fusible element (they can be made of wire, rod, stamped plates, etc.), a locking element and a spring are installed between them, a spring is compressed, and thrusts are put on the support petals. The locking mechanism is assembled. The locking mechanism is mounted in the housing, leading the elastic protrusions of the support 4 into the groove of the housing 1. The thermal shut-off valve is assembled.

The valve design according to the second embodiment differs only in that instead of rods, an emphasis 10 with elastic petals 11 is used, which are pulled together by a split ring 8, the ends of which are soldered by fusible material 9, similarly to the first embodiment. The diameter of the split ring is selected so that in its soldered state it is less than the diameter (cross section) of the locking element 5.

The assembly of this design of the thermal shut-off valve (option 2) differs somewhat from that given above for option 1. Initially, the elastic petals 11 of the stop 10 are pulled together by a split ring 8, the cut of which is fusible

material. The emphasis with the ring is installed in the housing 1 until it contacts the protrusion of the housing. Next, the shut-off element 5 is installed in the housing until it comes into contact with the tabs 11 of the stop 10, after which the spring 6 is brought to the shut-off element 5, loaded with a compressive force by moving the support 4, which is fixed with elastic protrusions in the groove of the housing 1. The shut-off valve according to the second embodiment is assembled .

Thermal shutoff valve operates as follows. We consider the valve operation simultaneously for the above options.

The thermal shut-off valve is installed in the gas supply line by means of elements 2 and 3.

In the initial position, the valve is in the open position and does not interfere with the supply of gas to consumers. In this position of the valve, the locking element 5 is not in contact with the surface "A" and is held by the latch (ring) 8. The elastic element 6 is compressed.

In an emergency, for example, in the event of a fire, when the temperature in the zone of the valve is exceeded, for which the fusible material 9 is designed, it melts and does not tighten the split ring, as a result of which the elastic element 6 is expanded, moving the locking element 5, which, due to the unloading force of the spring 6 extends the ring 8, passes through it and moves the locking element until it contacts the surface "A" of the housing 1, blocking the gas supply.

The developed design of the thermal shut-off valve is characterized by simplicity and reliability, manufacturability of the housing solution, ease of assembly, its small dimensions, which reduces its complexity, metal consumption, and ensures easy and convenient installation in the gas system.

Claims (2)

1. Thermal shut-off valve, comprising a hollow body, in which a shut-off mechanism is mounted, made in the form of an axially spring-loaded shut-off element, which is able to interact with the housing seating surface when the gas supply is shut off, characterized in that the valve is provided with a support fixed in the housing , the locking element is spring-loaded relative to the support, and the valve is additionally equipped with a latch and rods mounted on the support, covering the spring and the locking element, connected from axial movement by rods and a latch mounted on them, made in the form of a split ring, the ends of which are connected by a fusible element. 2. Thermal shutoff valve containing a hollow body, in which a locking mechanism is mounted, made in the form of an axially spring-loaded locking element relative to the housing of the locking element, which is able to interact with the housing seating surface when the gas supply is shut off, characterized in that the valve is equipped with a latch, an abutment with elastic with petals, a support fixed in the body, the locking element is spring-loaded relative to the support and rests on the petals of the stop fixed in the body, which are pulled together by a latch, you olnennym in the form of a split ring, the ends of which are connected by a fusible element.