RU67668U1 - THERMAL LOCK OF THE THERMAL VALVE - Google Patents

Abstract

The utility model relates to domestic and industrial gas units and is designed to protect gas supply systems in emergency situations, for example, to cut off gas in the event of a fire. The thermal lock of the thermal shutoff valve contains a rod, a thermosensitive element made of thermosensitive material, and a rod position lock, the lock being made with a recess in which the thermosensitive element is located, the rod is installed in the recess with an emphasis on one end of the thermosensitive element, and the other protruding from the lock the end in the valve, loaded with a spring and fixed in front of the saddle rod with the formation of a gap, and the latch is installed in the annular valve made in the cavity of the valve body point, the rod is perpendicular saddle axis, and temperature sensing element is disposed in the recess to form a gap with the inner walls of the recess. The result is an increase in the reliability and accuracy of the thermal lock of the thermal shut-off valve.

Description

The utility model relates to domestic and industrial gas units and is designed to protect gas supply systems in emergency situations, for example, to cut off gas in the event of a fire.

Known thermal lock thermal shutoff valve containing a latch with a rod located in the cavity of the latch with one end resting on the heat-sensitive element, and the other in the valve, loaded with a spring and located in front of the seat with the formation of an annular gap (see US patent No. 5472008, class F16K 17/40, 12/05/1995).

The disadvantage of this thermal lock thermal shutoff valve is the variation in temperature of the valve.

Also known is a thermal lock of a thermal shut-off valve containing a retainer, the internal cavity of which is filled with fusible material and a cylindrical rod fixing shutter is removed from it, the shutter installed in the body cavity opposite the seat, loaded with a spring and equipped with a stopper, the stopper being installed from the side opposite to the spring, and the shutter is made in the form of a ball mounted with an eccentricity relative to the axis of the passage of the seat (see patent RU No. 2149303, class F16K 17/40, 05.20.2000).

The specified thermal lock of the thermal shutoff valve, although devoid of the above drawback, however, it has an increased complexity of the technological identity of the gap through which the fusible substance flows out during melting.

The closest to the utility model in terms of technical nature and the achieved result is a thermal lock of a thermal shut-off valve containing a rod, a heat-sensitive element made of

a thermosensitive material, and a rod position retainer, wherein the retainer is provided with a cavity in which the thermosensitive element is located, channels are made in the retainer connecting its cavity to the valve cavity and serve for the outflow of molten thermosensitive material, the rod is installed in the recess with an emphasis at one end into the thermosensitive element, and the other protruding from the latch end into the bolt, loaded with a spring and fixed in front of the saddle rod with the formation of a gap, and the latch is installed in an annular groove in the cavity of the valve body, and the stem is perpendicular to the axis of the seat (see patent RU No. 2190792, CL P16K 17/40, 10/10/2002).

However, this thermal lock has an increased complexity of manufacturing associated with high-precision execution in size and geometric position of the channels for expiration, while it is possible false operation during its transportation, which is associated with a complex system of fixing the position of the ball, including several structural elements that during shaking during transport, they can release the ball from its original eccentric position relative to the seat.

The objective of the utility model is to simplify the design of the thermal lock and increase the reliability of fixing the ball in its original position under conditions of shaking and possible impacts during transportation and installation of the valve and reduce the complexity.

The technical result achieved by using this utility model is to increase the reliability and accuracy of the thermal lock thermal shut-off valve.

The problem is solved, and the technical result is achieved due to the fact that the thermal lock of the thermal shutoff valve contains a rod, a thermosensitive element made of a thermosensitive material, and a rod position lock, while the lock is made with

the recess in which the thermosensitive element is located, the stem is installed in the recess with one end resting on the thermosensitive element, and the other protruding from the retainer end into the valve, loaded with a spring and fixed in front of the saddle rod with a gap, and the retainer is installed in an annular ring made in the cavity of the valve body the groove, the stem is perpendicular to the axis of the seat, and the heat-sensitive element is located in the recess with the formation of a gap with the inner walls of the recess.

As a thermosensitive material, a polymeric material with a Wick heat resistance of less than 100 ° C or a polymeric material with shape memory can be used.

The annular groove is made with eccentricity relative to the saddle, and the latch is installed in the annular groove in the place of its greatest deepening in the body.

An analysis of the known designs of thermal locks of thermal shut-off valves showed that it is possible to increase the reliability of their work by simplifying the design of the thermal lock of the valve.

The design of the thermal lock, in which the heat-sensitive element is located in the recess with the formation of a gap with the internal walls of the cavity, allows, on the one hand, to simplify the design of the latch, in which it is not necessary to make holes to remove the molten heat-sensitive element from the recess, and on the other hand to reduce the likelihood of getting foreign objects, in this case, the remains of the heat-sensitive element, into the space between the shutter and the seat and thereby prevent leaky overlapping of the flowing hour and when the shutter valve in the saddle during the thermal response time termozapornogo lock valve, which increases the reliability of the thermal tripping lock termozapornogo valve. The implementation of the latch of a polymeric material with shape memory further increases

the reliability of the operation of the thermal lock by increasing the predictability of the behavior of the material from which the thermally sensitive element is made at the time the thermal lock is triggered. Since the heat-sensitive element is preferably made of a polymeric material with a Wick heat resistance of less than 100 ° C, i.e. of fusible material, it is possible to configure the thermal lock to operate in a fairly narrow temperature range at which the shape and / or melt of the heat-sensitive element of the thermal lock and the shutter moves in the direction of the saddle, and the implementation of the heat-sensitive element from polymeric materials that are easy to process further simplifies the manufacturing technology of the thermal lock.

The location of the latch in the deepest place of the annular groove allows more stable installation of the latch in the annular groove and thereby almost completely eliminates false valve actuation due to the displacement of the latch with the stem relative to the shutter, for example, during transportation of the valve due to shaking and possible axial impact loads, which may occur during loading and unloading. In addition, this arrangement of the retainer made it possible to almost completely locate it in the groove and a small part of the retainer and stem protrude from the latter, which reduces the hydraulic resistance in the flow part of the thermal shutoff valve due to a more uniform flow of gas around the shutter, which, in turn, accelerates the alignment process shutter position relative to the axis of the seat.

Figure 1 shows a longitudinal section of a thermal shut-off valve with a thermal lock.

Figure 2 is a section along aa in figure 1.

Thermal lock thermal shutoff valve contains located in the housing 1 for fixing the initial position of the shutter 2 latch 3. Shutter 2

loaded with a spring 4, mounted with emphasis in the support washer 5. The shutter 2 can be made in the form of a ball installed in the initial position with an eccentricity "e" relative to the axis of the saddle 6 opposite the latter. The latch 3 is installed in the cavity of the housing 1 in the annular groove 7 made in it and is made with a recess 8 in which the heat-sensitive element 9 and the stem 10 are located. The annular groove 7 is made with an eccentricity relative to the seat 6. The latch 3 is installed in the annular groove 7 in place of it the largest recess in the housing 1. The saddle 6 is made in the housing 1 with the formation of a ledge 11 at the entrance to it. The heat-sensitive element 9 is located in the recess 8 with the formation of a gap with the inner walls of the recess. The rod 10 is installed in the recess 8 with an emphasis at one end in the heat-sensitive element 9, and the other protruding from the latch 3 end into the valve 2, loaded with a spring 4 and fixed in front of the saddle 6 by the rod 10 with the formation of a gap, while the valve 2 in the initial position is installed with an emphasis into the ledge 11 and fixed in this position by the rod 10 located perpendicular to the axis of the saddle 6 and coaxial to the radius of the shutter 2 made in the form of a ball.

The supporting washer 5 is made with flexible tabs, providing the ability to enter it into the cavity of the housing 1 and subsequent locking, and a Central annular collar, centering the spring 4.

As a thermosensitive material, a polymeric material with a Wick heat resistance of less than 100 ° C or a polymeric material with shape memory is used.

Most preferably, the ratio of the volume V _{1 of the} recess 8 in the retainer 3, located under the stem 10 until the valve actuates, and the volume V _{2 of the} heat-sensitive element 9 is in the following relation:

V ₁ ≥V ₂ + S • e, where

S is the cross-sectional area of the recess, equal to the cross-sectional area of the rod inserted into this recess;

e - the amount of eccentricity with which the locking element 2 is installed relative to the seat 6.

Thermal lock thermal shutoff valve operates as follows. In the initial (open) position, the shutter 2, for example in the form of a ball, is located with an eccentricity "e" and focusing on the ledge 11 at the entrance to the seat 6, without blocking it. In an emergency, for example, when the temperature rises in the area of the thermal valve due to a fire, the heat-sensitive element 9, made of a polymer material with a Wick heat resistance of less than 100 ° C, first loses its structural strength, changing its shape and size in height under the influence the force of the spring 4 transmitted to the latch 3 by the valve 2, while the rod 10 is lowered into the recess 8, allowing the valve 2 to reduce its eccentricity "e" and move to the seat 6 in the closed position of the thermal shut-off valve, i.e. overlapping its passage opening.

The valve is closed, and the shutter 2 is held by the force of the spring 4 and the pressure of the working medium.

If the heat-sensitive element 9 is made of a polymeric material with shape memory, then it changes its shape (for example, increasing its thickness and at the same time decreasing its height), which allows the rod to move inside the recess 8, reducing the eccentricity "e" of the location of the shutter 2 relative to the seat 6, and allows the shutter 2 to move towards the seat 6.

The valve is closed, and the shutter 2 is held by the force of the spring 4 and the pressure of the working medium.

This utility model can be used wherever it is necessary to block the flow cross section of pipelines, in particular gas pipelines in emergency situations, for example during fires.

Claims (5)

1. The thermal lock of the shut-off valve, comprising a rod, a heat-sensitive element made of a heat-sensitive material, and a rod position lock, wherein the latch is made with a recess in which the temperature-sensitive element is located, the rod is installed in the recess with an emphasis at one end in the heat-sensitive element, and the other protruding from the retainer end - into the valve, loaded with a spring and fixed in front of the saddle rod with the formation of a gap, and the retainer is installed in the rings made in the cavity of the valve body a groove, and the stem is perpendicular to the axis of the seat, characterized in that the heat-sensitive element is located in the recess with the formation of a gap with the inner walls of the recess. 2. The thermal lock of the thermal shut-off valve according to claim 1, characterized in that a polymer material with a Wick heat resistance of less than 100 ° C is used as a heat-sensitive material. 3. The thermal lock of the thermal shut-off valve according to claim 1, characterized in that a polymer material with shape memory is used as the heat-sensitive material. 4. Thermal lock thermal shut-off valve according to claim 1, characterized in that the annular groove is made with an eccentricity relative to the seat. 5. Thermal lock thermal shut-off valve according to claim 4, characterized in that the latch is installed in the annular groove in the place of its greatest deepening in the housing.