DE20015378U1 - Gas flow switch - Google Patents

Description

Mertik Maxitrol GmbH & Co. KG

1
Description

Gas flow monitor
Technical area

The invention relates to a gas flow monitor for automatically shutting off gas lines when an inadmissible increase in flow occurs.

&iacgr;&ogr; State of the art

Such gas flow monitors, which are used in pipelines, for example in front of gas fittings, gas appliances, etc., are available in a wide variety of designs. They are used to interrupt the gas supply if gas consumption increases above a predetermined value.

For example, WO 92/01184 describes a gas flow monitor of the type mentioned above, referred to as a safety closing device, which closes the pipe system if damage occurs, but without causing the supply line to close prematurely if a consumer requires the amount of gas corresponding to his output over a longer period of time. In this safety closing device, a valve is designed as a disk valve.

The valve body is attached to a valve stem, which is mounted on both sides in plain bearings in the axial direction of the valve against the force of a spring. The valve plate interacts with a valve seat located in one of two ring disks, whereby the ring disks also serve as bearings for the plain bearings mentioned above. The ring disks are provided with recesses or openings.

Mertik Maxitrol GmbH & Co. KG
GA00/07EN

Since each flow value is assigned a defined value of the pressure loss at the open valve, a shift of the operating point on the pressure loss characteristic curve and/or a shift of the pressure loss characteristic curve of the safety closing device is necessary in order to be able to precisely adapt the closing flow to the type, nature and quantity of the consumers.

For this purpose, the spring force of the spring and/or the closing path of the valve can be adjusted. To adjust the closing path of the valve, a nut is provided at the free end of the valve stem, which is screwed onto a thread on the valve stem. An adjustment device arranged in the area between the two plain bearings, for example formed by a second nut, is used to adjust the spring force.

Furthermore, an automatic shut-off valve is known from GB - PS 556,863. This shut-off valve consists of a tubular housing with a connecting thread on both sides. In the housing there is an annular disc with openings, which has a sliding bearing in the middle for a longitudinally movable valve stem, which has a valve body at one end that interacts with a valve seat in the housing. A compression spring supported on the valve body on the one hand and on the annular disc on the other hand holds the valve body in the open position until the set closing flow is reached. To change the closing flow in this design, the setting of the spring force is changed by changing the screw-in depth of the valve stem in a hood, and thus the installation length of the spring.

A valve described in US Patent 3,794,077 has a similar structure. A compression spring, which is supported on the one hand by a plain bearing in the housing and also has openings, and on the other hand by a nut screwed onto the valve stem, holds the valve body in the open position until the set closing flow is reached. By changing the position of the nut, which is however secured against twisting by a pin, the valve body is in the open position.

Mertik Maxitrol GmbH & Co. KG
GA00/07EN

secured on the valve stem, the installation length of the compression spring and thus the closing flow are changed via the change in the spring force.

The disadvantage of these solutions is that setting a defined value for the closing flow requires a corresponding adjustment and testing device and is therefore primarily carried out by the manufacturer of such safety devices during production. A desired setting directly at the installation site, for example by the respective installation company, is practically impossible. Since a dependency of the closing flow of the safety device used on the possible nominal flow is desirable and in some cases also required in order to achieve the greatest possible safety, a relatively high number of variants must be available. This in turn results in increased production and storage costs.

Description of the invention

The invention is based on the problem of developing a gas flow monitor of the type mentioned, in which the setting/changing of the closing flow is possible without structural changes, such as the use of different springs depending on the desired closing flow, and thus even after production. In particular, it should be possible for the closing flow to be set outside the production facility, advantageously only at the time of installation. According to the invention, the problem is solved by arranging a spacer on the inlet guide, which forms a stop for the closing body when the gas flow monitor is in the open position.

This solution has been found which eliminates the previous disadvantage of the state of the art, namely that the setting of a defined value of the closing flow rate is primarily only carried out by the manufacturer of such safety devices during production due to the effort required to do so.

Mertik Maxitrol GmbH & Co. KG
GA00/07EN

Further advantageous embodiments of the invention emerge from the other claims. It is particularly advantageous if the spacer has locking areas that engage behind the webs of the input guide and the spacer is held in its position under the action of a spring that is supported on the one hand on the side of the input guide facing away from the closing body and on the other hand on the spacer itself.

In order to be able to set several different values of the closing flow with a spacer, it is possible in a further embodiment, for example, for each locking area to have different locking positions, the respective engagement of which can be realized by rotating the spacer by a rotation angle assigned to the locking positions, wherein the position of the stop for the closing body in the open position can be changed in the longitudinal direction of the pin depending on the locking position.

In this context, it proves to be particularly advantageous if, in this design, an unintentional adjustment of the set value is avoided by the spacer having an anti-twisting device, which, however, is deactivated when the spacer is moved against the force of the spring in order to enable an intentional change of the set value.

Furthermore, an embodiment has proven to be advantageous in which the spacer is held captive on the input guide by having a resilient lip assigned to each web of the input guide, which allows the web to snap over, whereas pins also assigned to each web of the input guide prevent it from being pushed out.

Example

The invention is described in more detail below using an exemplary embodiment. Shown are:

Mertik Maxitrol GmbH & Co. KG
GA00/O7DE

Fig. 1 shows a gas flow monitor in a sectional view in the open position. Fig. 2 shows a view A of the gas flow monitor from Fig. 1. Fig. 3 shows a view of the spacer from Fig. 1. Fig. 4 shows a view B of the spacer from Fig. 3.

The embodiment of a gas flow monitor according to the invention shown in Figure 1 has a tubular housing 1 which can be pressed into a gas line (not shown). The housing 1 is advantageously provided with an insertion bevel 2 for this purpose. In order to guarantee the necessary tightness between the gas line and the housing 1, the housing 1 has a circumferential groove 3 which serves as a receptacle for a CD ring (not shown). It goes without saying that another connection is also possible.

The housing 1 is provided with a recess 4 on the inlet and outlet sides. Between the two recesses 4, the housing 1 has a constriction 5, which is designed as a valve seat 6 on the side facing the inlet. An inlet guide 7 and an outlet guide 8 are pressed into the recess 4 on the inlet and outlet sides, respectively. In order to keep the area of the inlet guide 7 and the outlet guide 8 that reduces the flow cross-section as small as possible, these are advantageously designed as sheet metal parts that have three radial webs 10 that are evenly distributed around the circumference (Figures 2 and 4). The inlet guide 7 is provided in the middle with a bearing point 9 for a pin 11, the second bearing point 12 of which is formed by an adjusting element 13 screwed into the middle of the outlet guide 8. The pin 11 is guided longitudinally in the bearing points 9 and 12, and a closing body 14 is attached to it, for example by means of a press fit. To achieve the desired tightness when the gas flow monitor is in the closed position, the closing body 14 has an annular receptacle for an O-ring 15 that serves as an elastic sealing element. A closing spring 16 is supported on the adjusting element 13, the other end of which presses the closing body

Mertik Maxitrol GmbH & Co. KG GA00/07DE

by 14 in its open position. The open position is determined by the stop of the closing body 14 on a spacer 17 fastened to the input guide 7, which has stop points 18 for this purpose.

For fastening to the input guide 7, the spacer 17 is provided with locking areas 19 assigned to each web 10, which engage behind the webs 10 (Fig. 2). A spring lip 20 assigned to each web 10 allows the web 10 to snap over when the spacer 17 is mounted. The position of the web 10 before snapping over is shown in Fig. 3. After snapping over, also shown in Fig. 3 but this time in dashed form, the web 10 is prevented from being pushed out of the spacer 17 by means of pins 21 also assigned to the webs 10. The spacer 17 is held in its position under the action of a spring 22, which is supported on the one hand on the side of the input guide 7 facing away from the closing body 14 and on the other hand on the spacer 17.

In order to be able to set different closing flows, each locking area 19 has different locking positions, in this embodiment three, which are achieved by correspondingly rotating the spacer 17. In the illustrations shown, the webs are in the locking plane E1, which is conveniently formed by the pin 21. The other two locking planes are marked in Fig. 2 and 3 with E2 and E3 for at least one web 10 each. Depending on the selected locking position, the position of the stop points 18 for the closing body 14 is changed in the longitudinal direction of the pin 11 when it is open. The respective setting can be immediately recognized by markings 24 applied to the spacer 17.

In order to prevent an unintentional adjustment of the selected closing flow, each individual locking level is assigned a raised part which serves as an anti-twisting device 23 due to the effect of the spring 22. Only by an external force directed against the spring 22 is the spacer 17 pushed into

Mertik Maxitrol GmbH & Co. KG GA00/07DE

Longitudinal direction so that each web 10 is outside the influence of the anti-twisting device 23.

The operation of the gas flow monitor described in this embodiment is as follows:

The gas flow monitor is set at the factory to a specific value of the closing flow by adjusting the adjusting element 13 and using appropriate adjusting and testing devices. In order to

&iacgr;&ogr; closing flow rate to the type, nature and quantity of consumers, the position of the closing body 14 in the open position can be changed by using the corresponding locking position of the spacer 17 to set the desired closing flow rate. This shifts the pressure loss characteristic curve of the gas flow monitor and, depending on the spring constant of the closing spring 16, also the operating point, by a greater or lesser amount, thereby changing the closing flow rate. The gas flow monitor is then installed in a gas line in such a way that the gas flow direction indicated by the arrows in Figure 1 is maintained. Normally it is then in the position shown in Figure 1. The closing body 14 is held in the open position under the influence of the closing spring 16 which acts against the flow. If gas consumption exceeds the closing flow rate due to damage to a downstream gas line or a downstream defective consumer, the force of the closing spring 16 is overcome by the increase in flow and the closing body 14 assumes the closed position. The gas supply is interrupted.

Mertik Maxitrol GmbH & Co. KG

8 List of reference symbols

1 housing

2 insertion bevel

3 grooves

4 Turning

5 Constriction

6 Valve seat

7 Entrance guide

8 Exit guide

9 Storage location

10 Bridge

11 pen

12 Storage location

13 Adjustment element

14 Locking body

15 O-ring

16 Closing spring

17 Spacer

18 Anchor point

19 Rest area

20 Lip

21 cones

22 Spring

23 Anti-twist device

24 Marking E1 Locking level 1 E2 Locking level 2 E3 Locking level 3

Claims (5)

1. Gas flow monitor for automatically shutting off gas lines with a gas-tight housing ( 1 ) which has a valve seat ( 6 ) inside for a closing body ( 14 ) which is movable in the housing ( 1 ), with a pin ( 11 ) guiding the closing body ( 14 ), with an inlet guide ( 7 ) arranged in the flow direction on the inlet side in the housing ( 1 ) which has a bearing point ( 9 ) for the pin ( 11 ) and several radial webs ( 10 ), with an outlet guide ( 8 ) arranged in the flow direction on the outlet side in the housing ( 1 ) which has a bearing point ( 12 ) for the pin ( 11 ) and several radial webs ( 10 ), and with a closing spring ( 16 ) which is supported on the one hand on the outlet guide ( 8 ) and on the other hand on the closing body ( 14 ) which is supported by the spring force against the Flow direction is held in the open position, wherein the flow cross-section, area of the closing body ( 14 ) and forces are determined such that the closing body ( 14 ) leaves its open position at a defined value of the closing flow and is moved against the valve seat ( 6 ) of the housing ( 1 ), so that in the closed position the gas line downstream of the gas flow monitor is closed, characterized in that a spacer ( 17 ) is arranged on the inlet guide ( 7 ), which forms a stop ( 18 ) for the closing body ( 14 ) when the gas flow monitor is in the open position. 2. Gas flow monitor according to protection claim 1, characterized in that the spacer ( 17 ) is held in its position by means of locking areas ( 19 ) located on it, which engage behind the webs ( 10 ) of the inlet guide ( 7 ) and under the action of a spring ( 22 ) which is supported on the one hand on the side of the inlet guide ( 7 ) facing away from the closing body ( 14 ) and on the other hand on the spacer ( 17 ). 3. Gas flow monitor according to protection claim 2, characterized in that each locking region ( 19 ) has different locking positions, the respective engagement of which can be realized by rotating the spacer ( 17 ) by a rotation angle assigned to the locking positions, and that depending on the locking position, the position of the stop ( 18 ) for the closing body ( 14 ) in its open position can be changed in the longitudinal direction of the pin ( 11 ). 4. Gas flow monitor according to protection claim 3, characterized in that the spacer ( 17 ) has an anti-twisting device ( 23 ) which is deactivated when the spacer ( 17 ) is moved against the force of the spring ( 22 ). 5. Gas flow monitor according to one of the protection claims 1 to 4, characterized in that the spacer ( 17 ) has a resilient lip ( 20 ) associated with each web ( 10 ) of the inlet guide ( 7 ), which allows the web ( 10 ) to snap over, whereas pins ( 21 ) also associated with each web ( 10 ) of the inlet guide ( 7 ) prevent the web from being pushed out.