DE29820264U1 - Temperature sensitive shut-off valve - Google Patents

Description

Temperature-sensitive shut-off valve

The present invention relates to a temperature-sensitive shut-off valve, in particular for gas lines, with a housing having a passage and a valve seat and an assembly consisting of a holding element that can be positioned in the passage and has a bore that is central to the valve seat in the installed position, a closing body with a pin element arranged thereon that can be inserted into the central bore of the holding element, a spring that can be clamped between the holding element and the closing body, and a temperature-sensitive element that fixes the pin element of the closing body inserted in the bore of the holding element and projects transversely to the holding element into the bore of the latter.

Such temperature-sensitive shut-off valves are known, for example, from German utility model 296 06 948.5 or German utility model 295 11 991.8. Such shut-off valves comprise, on the one hand, a housing which has a gas passage and a valve seat into which a closing body can be inserted in a gas-tight manner. The closing body in turn has a pin-shaped element. A holding element is fixed in the housing at a point in the gas passage and has a bore which is essentially central to the valve seat. The pin arranged on the closing body is inserted into this bore with a spring between the holding element and the closing body. In the previously known shut-off valves, fusible link can either be introduced directly into the ring area between the central bore of the holding element and the pin, or a holding element is inserted radially to the central bore.

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fixed with fusible link, which in turn fixes the pin in the hole. If the temperatures rise undesirably, the fusible link melts and the pin is free from the central hole of the holding element. The spring force allows the appropriately positioned closing body to move into the valve seat and seal it gas-tight.

A disadvantage of the shut-off valves of this type known from the state of the art is that most of the temperature-sensitive components are located inside the housing. This results in a certain inertia, which cannot be met in terms of modern requirements with regard to closing times.

Particularly in the case of large shut-off valves, i.e. diameters of 65 to 150 mm, the temperature sensitivity of the previously known shut-off valves of this type is unsatisfactory. In particular, previously known valves are no longer suitable for meeting the current requirements for the closing time.

However, there are also shut-off valves in which the temperature-sensitive components are arranged on the outside, such as in DE-P 31 26 214.7-09 or in EP 0 432 371. However, the systems used in these are too complicated and too expensive.

Based on this state of the art, the present invention is based on the objective of developing a temperature-sensitive shut-off valve of the generic type in such a way that it reacts faster and more sensitively to a temperature increase even in large designs, can be manufactured economically and also provides an opportunity to improve the temperature sensitivity.

To solve this problem, the invention proposes that a part of the temperature-sensitive element is guided to the outside of the housing. The shut-off valve according to the invention has the advantage that a part of the temperature-sensitive element is positioned outside the housing and is therefore directly exposed to the temperature prevailing outside the housing. This means that the valve reacts better to

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Temperature increases. In addition, the element located outside the housing can be better influenced, so that the valve as a whole can be better adjusted to the desired closing temperature and closing time.

For the economical manufacture of the fitting, it is proposed that a support for the holding element be made in the gas passage of the housing and that the holding element be fixed in the housing by a snap ring inserted from the outside. The holding element advantageously has star-shaped webs, with a through-hole extending into the central hole being arranged in one of the webs. The temperature-sensitive element can be inserted into this through-hole. This advantageously comprises a pin and, according to a proposal of the invention, also a ball. If the pin element of the closing body has an annular groove, a ball is ideal for fixing the pin element in the central through-hole. The pin presses on the ball and extends through the housing to the outside, where, according to a proposal of the invention, it is held in a pot-shaped element by fusible solder. If the fusible link melts, the pin can move into the cup-shaped element, causing the ball to move out of the annular groove of the pin element of the locking body, so that the locking body is free and can move into the closed position.

To control the temperature sensitivity, the invention proposes coloring the pot-shaped element black. This makes it more temperature sensitive. According to an advantageous proposal of the invention, a slatted body can also be placed on the pot-shaped element. Alternatively, the slats can also be worked directly onto the pot. The pot and projecting slats can be made from one piece. Such slats also increase the temperature sensitivity.

According to a proposal of the invention, the top-shaped element is screwed into the housing in a gas-tight manner, if necessary with the interposition of sealing disks and/or using sealing adhesives.

For the base of the pot, the invention proposes not to machine the usual spanner flats, so that the gas consumers cannot unscrew the heat sensor with the commercially available spanners and

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Gas can be "tapped", as sometimes happens when there is talk of manipulation and the resulting gas accidents.

Rather, the base of the heat sensor should be designed in an unusual shape that can only be gripped with a special wrench provided by the fitting manufacturer.

According to an advantageous suggestion, the housing can be turned in one piece from metallic material, for example steel or stainless steel. Steel is required for these large designs.

The invention provides an economically manufacturable shut-off valve which can be designed to be sufficiently temperature-sensitive even in large designs.

Further advantages and features of the invention emerge from the present description based on the figures.

In it show

Fig.1 a sectional view of an embodiment of a temperature-sensitive shut-off valve and

Fig. 2 is a plan view of a lamella body.

The shut-off valve 1 shown in Figure 1 comprises a housing 2, which can in principle also be part of a gas valve, a gas line or the like. In the embodiment shown, the housing 2 is turned in one piece from metal, for example steel or stainless steel, and has flange connections 3. In principle, internal or external thread attachments can also be provided instead of the flanges 3. A gas passage is formed inside, with a first cylindrical piece 4 in a shoulder 5, above which an annular groove 6 is formed. After the shoulder 5, a recess 6 is formed, in which a snap ring is placed. An assembly is inserted into the housing 2, consisting of a holding element 8 placed on the shoulder 5, which in the installed position has a sleeve-shaped formation 9 and a

central bore 10. To fix the holding element in the housing, a snap ring 11 is inserted into the recess 6. In the embodiment shown, the holding element 8 has an outer ring area that is placed on the shoulder 5, an inner area formed by the sleeve 9 and concentric with the outer ring, and webs running in a star shape between them. In one of the webs 12 there is a through-bore 13 that reaches into the central bore 10.

A closing body 14 is connected to a pin 15 by means of a screw connection. The pin 15 has an annular groove 16. A spring 17 is clamped between the holding element 8 and the closing body 14. The closing body has a conical head that can be inserted into the funnel-shaped valve seat and can seal it gas-tight there.

The housing has a through hole 18 and the holding element 8 is inserted into the housing 2 in such a way that the hole 13 in the web 12 is aligned with the through hole 18 in the housing 2. The through hole 18 is widened towards the outside of the housing to form a threaded hole. A ball 19 is first inserted through the through hole and the hole 13 in the star-shaped web 12 of the holding element 8, which protrudes into the annular groove 16 in the pin 15. Then a pin 20 is inserted, which protrudes from the outside of the housing. A pot-shaped element 21 filled with fusible link 22 is screwed into the threaded hole from the outside of the housing. The pin 15 is fixed in the central bore 10 via the fusible link 22, the pin 20 and the ball 19, which is positioned in the annular groove 16 of the pin 15, and the closing body 14 is thus positioned against the force of the spring 17 relative to the holding element 8. When the temperature increases, the fusible link 22 melts so that the pin 20 and the ball 19 can move to the outside of the housing. The pin 19 is released and the closing body 14 moves into the closed position in the valve seat 7. The pot 21 can be colored black to improve the temperature sensitivity.

Figure 2 shows a lamella element 23, for example made of aluminum, which can be placed on the pot 21, whereby the temperature sensitivity is increased. The color of the pot, the type of lamellae, the amount of fusible link and the wall thickness of the pot can be used to

Temperature sensitivity can be influenced so that the desired closing temperatures can be set. Alternatively, the pot and slats can also be made from one piece.

The embodiment described is for illustrative purposes only and is not restrictive.

Reference list

1 shut-off valve

2 housings

3 Flange

4 cylindrical gas passage

5 paragraph

6 Ring groove

7 Valve seat

8 Holding element

9 Sleeve

10 Bore

11 Snap ring

12 Bridge

13 Bore

14 Locking body

15 pen

16 Ring groove

17 Spring

18 Through hole

19 ball

20 pen

21 Pot

22 Fusible link

23 Slat element

Claims (10)

Expectations 1. Temperature-sensitive shut-off valve, in particular for gas lines, with a housing having a passage and a valve seat and an assembly consisting of a holding element that can be positioned in the passage with a bore that is central to the valve seat in the installed position, a closing body with a pin element arranged thereon that can be inserted into the central bore of the holding element, a spring that can be clamped between the holding element and the closing body and a temperature-sensitive element that fixes the pin element of the closing body inserted in the bore of the holding element and projects transversely to the holding element into the bore of the latter, characterized in that that part of the temperature-sensitive element is led to the outside of the housing. 2. Temperature-sensitive shut-off valve according to claim 1, characterized in that the holding element is fixed in the housing by a snap ring. 3. Temperature-sensitive shut-off valve according to one of the preceding claims, characterized in that the holding element has star-shaped webs, wherein in at least one of the webs a through-bore is arranged which extends into the bore, in which the temperature-sensitive element is inserted. 4. Temperature-sensitive shut-off valve according to one of the preceding claims, characterized in that the temperature-sensitive element has a pin which is held in a holding position with fusible link. 5. Temperature-sensitive shut-off valve according to one of the preceding claims, characterized in that the temperature-sensitive element has a ball which is pressed by the pin against the pin element of the closing body. 6. Temperature-sensitive shut-off valve according to one of the preceding claims, characterized in that a pot-shaped element is arranged on the outside of the housing as part of the temperature-sensitive element, which contains fusible link and positions the pin in a holding position. 7. Temperature-sensitive shut-off valve according to claim 6, characterized in that the pot-shaped element is colored black. 8. Temperature-sensitive shut-off valve according to one of claims 6 or 7, characterized in that a lamellar body is placed on the pot-shaped element. 9. Temperature-sensitive shut-off valve according to one of claims 6 to 8, characterized in that the temperature-sensitive element is screwed into the housing in a gas-tight manner. 10. Temperature-sensitive shut-off valve according to one of the preceding claims, characterized in that the housing is a one-piece metal turned part. RS/kr/wr