DE102011010046B3 - Excess flow valve - Google Patents

Abstract

A gas flow monitor is to be created in which the closing flow rate has the same value regardless of the installation position. Furthermore, it should have a damping function in order to avoid closing in the event of brief flow peaks. Construction and manufacture should be as simple as possible. Gas flow monitor with a closing body (1) which is held open against the gas flow up to a limit value by a spring (6) and which is pressed against a valve seat (13) when this limit value is exceeded, the closing body (1) being rotatable in the direction open the valve seat (13) is mounted and the center of gravity of this rotatably mounted closing body (1) is on this axis of rotation (3). The gas flow monitor is used to automatically shut off downstream gas lines when a defined maximum flow rate is exceeded

Description

Technical area

The invention relates to a gas flow monitor for automatically shutting off downstream gas lines, with a closing body which is held open by a spring against the gas flow up to a limit and which is pressed when exceeding this limit against a valve seat, according to the preamble of the first claim.

State of the art

Gas flow monitors are known in many different versions. They are installed in gas pipes, for example, before gas fittings, gas appliances, etc. They are designed for a predefinable nominal flow. At a closing flow above this nominal flow, as is the case, for example, with pipe breaks, tampering or impermissibly high leakage, the closing body is moved into the sealing position and the subsequent gas line shut off.

Such a device for shutting off a pipeline is exemplified in DE 10 2004 024 525 A1 known. In this device is located in a housing in an open position outside of the airfoil serving as a shut-off pivoting disc, whose also lying outside the airfoil pivot axis is arranged in each case downstream.

All these statements have in common that they are based on a defined closing flow rate, ie. H. the gas flow, at which closes the gas flow monitor, are adjusted. Due to the safety requirements, there are narrow limits for the deviations resulting from manufacturing tolerances.

This means that the value of the closing flow rate applies only to the existing installation position of the gas flow monitor in the adjustment made, because in the adjustment the self-weight of the valve disk and possibly further combined with him items is received. Thus, the gas flow monitors have a higher closing flow vertically upwards in the installation position than in the case of horizontal installation. Thus, different variants must be available for the different mounting positions. This in turn has an increased production and storage costs result.

A gas flow monitor, which makes do with a uniform adjustment for different installation positions, for example, from DE 10 2005 009 438 A1 known. This gas flow monitor is designed such that the valve axis formed by a valve seat, a valve seat associated closing body and a guide for the closing body is inclined relative to the housing axis. Due to the inclined arrangement of the axis of the valve seat, guide and closing body valve to the axis of the housing in which the valve is located, there are several mounting positions in which the influence of the weight of the moving parts on the spring force is identical, so that results in the same closing flow in all these mounting positions.

The disadvantage of this solution is that the housing next to the gas inlet and gas outlet has an additional opening, the gas-tight and above all things must be closed as tamper-proof. The structure itself is very complicated to manufacture. Furthermore, care must be taken in an installation in a horizontal position that the inclined valve axis assumes a prescribed position, so that the adjusted closing flow rate is maintained. This is often associated with difficulties, especially when the housing must be screwed into a pipeline.

Another gas flow monitor, which can be used with a uniform adjustment in different mounting positions, is in the DE 10 2006 028 466 A1 described. Here, the valve seat of the valve body is formed by an elastic sealing element against which the shut-off body rests in the closed position. By this measure, the shut-off becomes easier, so that the weight-related influences resulting from the installation position are minimized.

Despite a minimization of weight results in the different installation positions by the different acting weight of the moving during the closing parts and the different friction conditions, a fluctuation of the value for the closing flow, which enters into the conceded deviations for the manufacturing tolerances, and thus is no longer available , so that the production side increased expenses are necessary to stay within the maximum allowable deviations.

Particularly problematic proves compliance with the allowable deviations of the closing value when it comes to gas flow monitor with very small pressure difference, as required especially in domestic installations, because here the spring force must be particularly low, so the weight of the valve disk has a greater share ,

This solution is also unsuitable for gas flow monitors which have a damping function in order to prevent a short-term flow closure in the downstream flow system in the gas flow monitor. To achieve the damping function additional structural expenses are required, which also have a higher weight result.

Furthermore, the position of the elastic sealing element as a valve seat for optimal fluidic design of disadvantage, since it can lead to an increase in the pressure loss.

In the DE 10 2007 008 285 A1 a position-independent flow monitor and a corresponding connection arrangement is described. In this solution, a means for increasing the flow rate of the medium flowing in the flow channel medium is provided. Due to the increased flow rate, the force acting on the shut-off body force is increased so that the weight of the shut-off in comparison is small.

Again, if only relatively, only a weight minimization. Furthermore, fluidic problems, in particular a higher pressure loss, occur due to the additional bottleneck, which leads to the disadvantages already described above.

From the DE 20 2009 010 613 U1 Furthermore, a gas flow monitor is known, with a gas-tight housing, which has a valve seat for an axially movable closing body which is held by spring force against the flow in the open position, the game of this storage in the open position is greater and continuously narrows at the beginning of the closing movement.

In this embodiment, the only possible installation positions of the housing of the gas flow monitor are the horizontal installation and the vertical installation with the flow direction upwards.

Presentation of the invention

The present invention is based on the problem to develop a gas flow monitor of the type mentioned, in which the closing flow has the same value regardless of the installation position. Furthermore, he should have a damping function to avoid closing in short-term flow peaks. Construction and production should be as simple as possible.

According to the invention the problem is solved in that in a gas flow monitor with a closing body which is held open by a spring against the gas flow up to a limit and which is pressed when exceeding this limit against a valve seat, the closing body rotatably mounted in the direction of the valve seat is and the center of gravity of this rotatably mounted closing body is located on this axis of rotation.

Thus, a solution was found with which the above-mentioned disadvantages of the prior art have been eliminated. This solution results in all possible installation positions of the gas flow monitor.

Further advantageous embodiments of the invention will become apparent from the other claims.

Thus, it proves to be advantageous for a simple production, if in a gas flow monitor of the type mentioned the weight balance of the rotatably mounted closing body is achieved by an integrally connected thereto counterweight.

A further preferred embodiment of the invention results when the counterweight strikes in the open position of the closing body on a base body which has a conical stop.

This embodiment of the invention serves to realize a damping function, which is always desirable when it comes to short-term flow peaks in the gas flow monitor downstream piping that are so far above the normal consumption that the set closing flow is exceeded. As an example, only gas appliances are mentioned, which are switched by a sudden opening solenoid valve. By this damping function occurs even at a set closing flow close to the normal consumption, as it is desirable for safety reasons, no accidental closing of the gas flow monitor.

For this purpose, the cup-shaped conical stop in the open position is surrounded by a counterweight located in the recess so that a space is formed. The necessary during a movement of the closing body volume compensation on the conical stopper and the inner wall of the recess formed throttle point leads during the occurrence of a flow peak to the delayed beginning of a closing movement of the closing body, so that it is brought back into its open position after the decay of the flow peak by the spring ,

In order to perform an installation-related adjustment as simple as possible, it proves to be beneficial if the spring is adjustable.

A further preferred embodiment of the invention with respect to a simple production results when the valve seat, the conical stop and the recording of the adjustable spring are integrally located on the body.

So that different nominal flow rates can be adjusted in a simple manner, a design proves to be particularly favorable, in which the closing body is preceded by a Strömungsleitring which is rotatable in the cylindrical housing, resulting in the rotational positions different flow cross-sections in connection with the closing body.

In order to set predetermined nominal flow rates, it proves to be advantageous if the flow guide has locking lugs, which protrude into corresponding grooves of the body.

Another possible embodiment of a gas flow monitor according to the invention is that two symmetrically arranged to the rotation axis rotary vanes form the closing body and their associated two valve seats are available. In this case, a rotary wing is favorably kept open by an arm of a torsion spring against the gas flow and the storage of the other arm designed adjustable.

In order to set predetermined nominal flow rates in this embodiment, it proves to be advantageous if a rotary leaf in the open position bears against a stop which can assume different positions.

embodiment

Exemplary embodiments of a gas flow monitor according to the invention will be described in more detail below with reference to exemplary embodiments. Show it:

1 a sectional view of a gas flow monitor according to the invention in a schematic representation in the open position,

2 a sectional view of a gas flow monitor according to the invention in a schematic representation in the closed position,

3 a view of the body in the section CC from 1 .

4 a view of another embodiment of a gas flow monitor according to the invention in a schematic representation in the open position,

5 a sectional view of a gas flow monitor according to the invention 4 in a schematic representation in the closed position in the section BB from 6 .

6 a sectional view of a gas flow monitor according to the invention 4 in a schematic representation in the closed position in the section AA from 5 ,

7 a view of the body in the cross section DD from 6 , In the 1 a first embodiment of a gas flow monitor according to the invention is shown in the open position. The gas flow monitor has a tubular housing in this example shown 14 on, which is connected to one of the known in the art and therefore not shown here possibilities with a gas line. In the by a directional arrow 2 Directed direction can be gas through the housing 14 flow through.

In the case 14 there is a basic body 5 , which is the flow opening of the housing 14 partially closes. The in the main body 5 formed off-center opening 17 is from a pipe directed against the flow 7 includes, the two parallel ribs 8th has, each serving as a bearing for a pin hole 10 exhibit ( 3 ). The pin serves as a rotation axis 3 for a rotatably mounted plate-shaped closing body 1 over the ones in the neck 7 located opening 17 is closable. To achieve the desired tightness in the closed position of the gas flow monitor has the nozzle 7 an annular groove for a valve seat 13 Serving O-ring. In the closing body 1 there is still an overflow opening 27 which ensures an automatic reopening after removal of the cause.

The closing body 1 is integral with a counterweight 4 connected, which is arranged and designed so that it is located outside the flow area and as weight compensation for the closing body 1 serves, so the center of gravity of the closing body 1 in the axis of rotation 3 lies.

On the neck 7 facing side of the closing body 1 there is a spring 6 At the other end of a shot 24 of the basic body 5 supported. Via an adjustment element 29 , designed to be screwed in this example, is the spring 6 adjustable.

On his counterweight 4 facing side is on the neck 7 a cup-shaped stop 12 formed, the open position of the closing body 1 limited. In this case, the outer circumferential surface is designed so that they are in the direction of the counterweight 4 conically tapered. This stop 12 is one in the counterweight 4 located recess 30 assigned in such a way that, in the open position, an almost closed space 31 results. In this case, form the outer surface of the stop 12 and the inner wall of the recess 30 an annular gap that occurs during a movement of the closing body 1 forms a throttle point for the necessary volume compensation.

Upstream is the main body 5 a on the inner wall of the housing 1 attached rotating flow guide ring 11 upstream, the inner wall 20 is formed so that at different rotational positions different flow cross-sections with the closing body 1 result, for example, by the distance between the inner wall 20 and the centerline of the housing 1 is executed differently. This makes it possible in a simple manner to adapt the gas flow monitor to different power levels.

To enable the setting of predetermined flow cross sections quickly, the flow guide ring 11 in the direction of the main body 5 several locking lugs 9 on, over in the main body 5 located grooves 32 the respective rotational position of the flow guide 11 fix.

This version is particularly suitable to be made of plastic parts and is characterized by its simplicity.

In the 1 the gas flow monitor is shown in its open position at the largest flow cross-section. Due to the existing weight balance of closing body 1 and counterweight 4 becomes the closing body 1 under the force of the spring 6 held until the adjusted closing flow, regardless of the installation position. This is the counterweight 4 on the conical stop 12 on.

The short-term occurrence of a flow peak whose value is above the closing flow occurs due to the throttling effect of the outer surface of the stop 12 and the inner wall of the recess 30 formed annular gap not for sudden closing of the gas flow monitor, but only at the beginning of a delayed closing movement. After the decay of the flow peak is the closing body 1 through the spring 6 brought back into its open position. However, if the closing flow is exceeded over a longer period of time, as is the case with a pipe break, then the gas flow monitor assumes the closed position, as in the 2 is shown. After removing the cause of the cause via the overflow 27 a pressure equalization and the gas flow monitor opens again.

A schematic representation of another embodiment of a gas flow monitor according to the invention in the open position is in the 4 to 7 shown.

A basic body 5 is by means of a sealing ring 28 gas-tight in the housing 14 arranged. The main body is centered 5 an upstream attachment 25 on that as a rotation axis 3 for two symmetrically arranged rotary blades 15 serves those on the main body 5 located valve seats 13 assigned. Both rotary wings 15 together form the closing body. About a seal 16 is a gas-tight closure of the body 5 formed outflow channels 26 guaranteed.

On the tower 25 is also a torsion spring 18 stored. An arm of the torsion spring 18 becomes adjustable in one on the main body 5 located storage 19 held while by the other Ami the torsion spring 18 via a spring receiver 21 a rotary wing 15 held open against the flow.

In order to allow the setting of predetermined flow cross sections also in this embodiment, has the main body 5 molded sleeves at associated locations 23 for a plug-in stop 22 on, the respective maximum open position of the rotary wing 15 Are defined.

In the main body 5 Also in this embodiment is an overflow 27 to equalize the pressure after eliminating a cause of the shutdown so that the gas flow switch opens again.

LIST OF REFERENCE NUMBERS

1

closing body

2

arrow

3

axis of rotation

4

counterweight

5

body

6

feather

7

Support

8th

rib

9

locking lug

10

drilling

11

flow directing

12

Conical stop

13

valve seat

14

casing

15

rotary wing

16

poetry

17

opening

18

torsion spring

19

storage

20

inner wall

21

spring mount

22

attack

23

shell

24

admission

25

essay

26

outflow channel

27

overflow

28

seal

29

adjusting

30

recess

31

room

32

groove

Claims (10)

Gas flow monitor with a closing body, which is kept open by a spring against the gas flow up to a limit value and which is pressed when exceeding this limit value against a valve seat, characterized in that the closing body ( 1 ) rotatable in the direction of the valve seat ( 13 ) is mounted, and the center of gravity of this rotatably mounted closing body ( 1 ) on this axis of rotation ( 3 ) is located. Gas flow monitor according to claim 1, characterized in that the weight balance of the rotatably mounted closing body ( 1 ) by an integrally connected with this counterweight ( 4 ) is achieved. Gas flow monitor according to claim 2, characterized in that the counterweight ( 4 ) in the open position of the closing body ( 1 ) on a base body ( 5 ) and with this a conical stop ( 12 ). Gas flow monitor according to claim 1, characterized in that the spring ( 6 ) is adjustable. Gas flow monitor according to claims 1 to 4, characterized in that the valve seat ( 13 ), the conical stop ( 12 ) and the recording ( 24 ) adjustable spring ( 6 ) integrally on the base body ( 5 ) are located. Gas flow monitor according to claim 1, characterized in that the closing body ( 1 ) a flow guide ring ( 11 ), which in a cylindrical housing ( 14 ) is rotatable and in the rotational positions are different flow cross-sections with the closing body ( 1 ). Gas flow monitor according to claims 1 and 6, characterized in that the flow guide ring ( 11 ) Latching lugs ( 9 ), which into corresponding grooves ( 32 ) of the basic body ( 5 ) protrude. Gas flow monitor according to claim 1, characterized in that two symmetrical to the axis of rotation ( 3 ) arranged rotary wings ( 15 ) the closing body ( 1 ) and their associated two valve seats ( 13 ) available. Gas flow monitor according to claims 1 and 8, characterized in that a rotary wing ( 15 ) by an arm of a torsion spring ( 18 ) is held open against the flow and the storage of the other arm is adjustable. Gas flow monitor according to claims 1 and 8, characterized in that a rotary wing ( 15 ) in open position on a stop ( 22 ), which can take various positions.

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