DE20116899U1 - Flow switch - Google Patents

Description

bTENGER, VVATZKE & RffVC KaiVe'r-Friedrich-Ring 70

D-40547 DÜSSELDORF

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PATENT ATTORNEYS

DIPL.-ING. WOLFRAM WATZKE (-1999)

DIPL.-ING. HEINZ J. RING

DIPL.-ING. ULRICH CHRISTOPHERSEN

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DIPL.-ING. WOLFGANG BRINGMANN

PATENT ATTORNEYS

EUROPEAN PATENT ATTORNEYS

Metallwerke Otto Dingerkus GmbH On the shield

57439 Attendorn

Our ref. 01-1009 Our ref.

Your reference Your ref.

Date

October 12, 2001

Flow barrier r

The invention relates to a flow monitor for automatically shutting off fluid-flowing lines when a fluid flow exceeds a defined maximum flow, with a housing delimiting a flow channel and having a valve seat on the inside, and a closing body arranged in the housing, wherein the closing body is held in a normal state by a retaining force in an open position in front of the valve seat in the flow direction and is moved against the valve seat by a fluid flow exceeding the defined maximum flow and seals off a part of the flow monitor that is fluidically downstream of the valve seat from the fluid flow.

There are a large number of such flow monitors and they are used in a wide variety of fluid line systems. They prevent excessive fluid flow through the line, which can occur, for example, in the case of leaks in the line system. By using such a flow monitor, a high fluid leak caused unintentionally or through manipulation and intention is detected and the line system is closed. This means that faults caused by lines breaking off or screw connections opening can be detected and the pipe system can be cut off from the fluid flow. In addition to the accidental opening of the system, the use of the flow monitor can also prevent manipulation of the entire fluid-carrying system, as already mentioned above. In gas systems in particular, gas accidents caused by gas theft with criminal intent or in cases of suicide can thus be prevented.

Telephone Fax

(0211) 572131 (0211) 588225

BHF-Bank, Düsseldorf (bank code 30020500) 40113276

Stadt-Sparkasse, Düsseldorf (bank code 30050110) 10090769

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Generic flow monitors can be used for both gas lines and liquid lines, such as water lines. Flow monitors are used for safety reasons, particularly in pipe systems that carry flammable gases such as natural gas or similar.

If an excessively high fluid flow occurs, for example due to a leak downstream of the closing body, the closing body is moved by the flow pressure and against the retaining force in the direction of the valve seat until it seals against it. The flow monitor is then closed and the part of the fluid line downstream of the closing body is sealed off. The fluid pressure building up on the upstream side of the closing body holds the closing body securely in the closed position.

If the cause of excessive flow, such as the leakage downstream of the closing body mentioned above, has been eliminated, the line system can be released for fluid flow again. However, the closing body is still held in the closed position in the valve seat by the fluid pressure generated upstream. To release it, the closing body must be returned to the open position, i.e. "reset".

One way of returning the closing body to the open position is shown in the German utility model DE 298 09 839 LH. When the flow monitor is triggered, a pin connected to a button arranged outside the housing is guided sideways against the closing body by pressing the button. This causes the closing body to tilt and open a gap so that the pressure built up upstream of the closing body can be released. The closing body then returns to its open position driven by the retaining force. The closing body is connected to a closing pin guided in a guide sleeve, with a clearance left between the closing pin and the guide sleeve. This clearance is necessary in order to be able to slightly tilt the closing body and with it the pin guided in the guide sleeve to release the opening when the flow monitor is triggered. This clearance, however, requires that exact and accurate guidance

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of the closing body is not possible. In particular, there is a risk that a flow monitor that has already been triggered several times will fail after several reset processes due to the repeated jamming between the guide pin and the guide sleeve in the area of the clearance. In the worst case scenario, if it is triggered, the closing body can no longer move completely into the valve seat and seal it, and fluid can continue to enter the part of the line system downstream of the closing body. In the case of a flammable gas, flammable gas can escape into the environment in the event of a line leak despite the flow monitor being triggered, with the immediate danger that this entails.

Furthermore, with a flow monitor according to DE 298 09 839 there is a risk that a manipulation, for example by intentionally blocking the side button that carries out the reset function, will prevent safe closing by locking the button in the unlocking position. A flow monitor manipulated in this way can no longer close the line safely and reliably in the event of an excessively high fluid flow, for example due to a leak.

Based on this prior art, it is the object of the invention to provide a flow monitor of the type mentioned at the outset, in which the flow monitor can be reset after a triggering event without moving the closure body transversely to the triggering direction.

To achieve this object, the flow monitor according to the invention has, in a section of the housing located behind the valve seat as seen in the direction of flow, an opening which can be closed in a fluid-tight manner and which runs transversely to the flow channel through the housing.

In the triggered state of the flow switch, after the cause of excessive fluid flow has been eliminated, the opening can be connected to a source of pressurized fluid. The pressurized fluid is introduced through the opening into the line area downstream of the valve seat, and the pressure that builds up compensates for the counterpressure on the upstream side of the closing body until the closing body is finally driven back into the

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The flow monitor is then open again, the source of a fluid under pressure can be separated from the opening and the opening can be closed fluid-tight again. The flow monitor is then ready for use again. Because the flow monitor is not reset by a mechanical force acting transversely to the direction of release, but by pressure introduced through the opening, the closing body can be guided without play. The risk of the guide being knocked out and thus the closing body jamming when triggered, with the consequences mentioned above, which exists with the state of the art mentioned at the beginning, does not exist.

In addition, the opening through the housing according to the invention can be used for other purposes. For example, it is possible to connect measuring instruments, such as a pressure measuring instrument, to the opening and, for example, to measure the pressure in the pipe system during normal operation of the flow monitor in the pipe system. Alternatively, samples of the fluid flowing in the pipe system can be taken and analyzed through the opening provided in the housing. In order to be able to open the opening provided in the housing safely during normal operation, it must be chosen to be significantly smaller than the cross-section of the flow channel. For example, in the case of a gas valve with a gas line cross-section of DN15 or DN25, a gas quantity that could create an explosive and therefore dangerous mixture cannot escape through an opening through the housing with a cross-sectional diameter of 1 mm. With an opening of such a small diameter, there is also no increase in flow so great that the flow monitor is triggered.

The opening through the housing according to the invention can be easily implemented using a tap hole. In order to avoid a large volume of fluid flowing out when the opening is open and thus possibly triggering the flow monitor, the cross-section of the opening should be chosen to be significantly smaller than the cross-section of the flow channel. The cross-section ratio is preferably chosen to be 1:100 or less.

In order to be able to easily connect the required devices, such as a source of pressurized fluid or measuring devices, to the opening, it is proposed that the opening be widened towards the outside of the housing and provided with a connection structure, preferably a connection thread. A screw plug is proposed as a simple solution for gas-tight sealing. To seal the opening closed with the screw plug, a seal is preferably inserted between a shoulder formed in the widened opening and a peripheral edge of the screw plug.

In order to be able to dimension the flow monitor as a whole and to save material, it is proposed that in the area of the opening the housing has a pin-like extension running transversely to the flow channel, in which the opening is guided from the flow channel to the outside of the housing.

Further features and advantages of the invention will become apparent from the following description of an embodiment with reference to the accompanying figures.

Fig. 1: in sectional view an embodiment of a flow monitor according to the invention and

Fig. 2: the flow switch shown in Fig. 1 in the release position and connected to a ball valve which is connected downstream of the flow switch and shown closed in the illustration, with a service device in the form of a rubber bag air pump being connected to the opening formed in the housing of the flow switch.

In Fig. 1, a flow monitor 1 according to the invention is shown in cross section in the normal or open position. The flow monitor 1 has a substantially cylindrical housing 2 through which a flow channel 3 is led. In this position, a fluid, for example a gas, can flow through the housing in the flow direction 4. The flow monitor 1 shown

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flow monitor 1 is designed as a single component and can be connected to other line sections via an internal thread 13 formed on the inlet side of the housing 2 and an external thread 14 formed on the outlet side of the housing 2. The housing 2 has a conical valve seat 5 approximately in the middle. A closing body 6 is arranged opposite the conical valve seat 5 in the open position against the flow direction 4, which has a conical closing surface complementary to the shape of the valve seat 5 with a seal 7 inserted therein. A guide pin 8 is fastened to the closing body 6 and is arranged parallel to the axis of the flow channel 3, extending from the closing body 6 in the direction opposite the valve seat 5. The guide pin 8 extends through an opening formed centrally in a support element 9 and is additionally guided by an extension 18 attached to the support element 9. The support element 9 is star-shaped with radially extending webs which rest on a shoulder formed on the inside of the housing 6 and are fixed in place by caulking the housing. The fluid flows in the direction of flow 4 through the spaces left between the webs. At the end opposite the closing body 6, the guide pin 8 has annular grooves 12a to 12c, three annular grooves in the embodiment shown. An adjusting ring 11 is locked in one of the annular grooves, in the embodiment shown in the outermost annular groove 12a. A helical spring 10 is arranged between the adjusting ring 11 and the extension 18 of the support element 9 and exerts a compressive force on the adjusting ring. This compressive force forms a retaining force which holds the closing body 6 in the open position. By displacing the adjusting ring 11 into one of the other annular grooves 12b or 12c shown, the pressure force exerted by the coil spring 10 and thus the retaining force can be changed, in this case increased.

In the flow direction 4 behind the valve seat 5, a tap hole 15 can be seen, which is essentially perpendicular to the axis of the flow channel 3 and extends to the outside of the housing. The tap hole 15 is widened in the direction of the outside of the housing, with the widening being provided with a thread 19 formed on the inside. The widened tap hole 15 is arranged in a pin-like widening 20 formed in one piece on the housing. The tap hole 15 is shown in the drawing.

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by means of a screw bolt 16 screwed into the enlarged tap hole it>, whereby a seal 17 is inserted between a shoulder formed in the extension 20 and a head of the screw plug 16 to seal the closed tap hole 15 in a fluid-tight manner. The part of the tap hole 15 with the smallest diameter has a diameter of 1 mm. In a flow monitor 1 used in a gas line, only such a small amount of gas escapes through a tap hole 15 with such a small diameter, even when the screw plug 16 is removed, that insufficient gas is generated to form an explosive mixture. The sealing plug 16 can therefore also be removed during normal operation of such a gas line. If tap holes 15 with a larger diameter are to be used, it is necessary for safety reasons to use a safety plug that can only be opened with a special tool instead of a normal plug 16 that has a conventional screw attachment. In addition, the larger the hole is, the more likely the flow switch will respond depending on a preset value.

The flow monitor works as follows:

When the fluid flow through the flow channel 3 does not exceed a maximum value, the fluid flows through the spaces left between the webs of the support element 9, flows around the closing body 6, passes the valve seat 5 and leaves the flow monitor on the outflow side. If the fluid flow passing through the flow monitor exceeds a previously determined maximum flow, the closing body 6 is moved in the direction of the valve seat 5 by the increasing flow pressure against the retaining force exerted by the coil spring 10. Once there, the closing body 6 closes the flow channel 3 in a fluid-tight manner by means of the seal 7 resting on the valve seat 5, so that fluid can no longer pass through the flow monitor 1. On the inflow side, the fed fluid builds up a fluid pressure that is higher than on the outflow side, which presses the closing body 6 against the valve seat 5 and creates a reliable seal.

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If the cause of an excessively high fluid flow in the line system in which the flow monitor 1 is integrated has been eliminated, the flow monitor 1 must be reset to release the line. To do this, the closing body 6 must be moved from its closed position in the valve seat 5 back to its open position. To achieve this, the sealing plug 16 is released from the thread 19 and removed from the tap hole 15. A connection fitting for connecting to a source of pressurized fluid, for example a pressurized gas, is now connected to the freed thread 19 and pressurized gas is introduced through the tap hole 15 into the area of the flow monitor located behind the valve seat 5 in the flow direction 4. If the pressure of the introduced fluid is high enough to compensate for the pressure on the side in front of the closing body 6 in the direction of flow 4, the closing body 6 is returned to the open position by the force of the coil spring 10 and the flow monitor 1 is ready for operation again. Now all that is required is to discharge the excess pressure of the fluid in the line system in a controlled manner and to remove the source of pressurized fluid connected to the branch hole 15 and to reinsert the sealing plug 16. The line in which the flow monitor 1 is integrated is then ready for operation again.

The connection to the flow channel 3 established via the tap hole 15 through the housing 32 can be used for other purposes in addition to resetting the flow monitor 1 from the triggered state to the normal state. For example, other components, such as measuring instruments, can be connected to the flow channel 3 via the thread 19. In this way, it is possible to carry out measurements, such as pressure measurements or measurements of the composition of the fluid flowing in the line, via the tap hole 15 during normal operation of the line system in which the flow monitor 1 is integrated.

The branch hole 15 thus offers several possible uses and can therefore be described as a "multifunctional connection".

In Fig. 2, the embodiment of a flow monitor 1 shown in Fig. 1 is connected to another fitting, a ball valve 21

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shown. The ball valve 2i is connected downstream of the flow switch 1 in terms of flow technology. With its external thread 14, the flow switch 1 is screwed sealingly to an internal thread 22 of the ball valve 21. In the position shown, the flow switch 1 is triggered, the closing body 6 has moved from its rest position resting on the support element 9 into the closed position in which it rests on the valve seat 5 with the seal 7 and closes the flow channel 3. To do this, it has overcome the counterforce exerted by the coil spring 10, the coil spring 10 is tensioned.

To reset the flow monitor 1, the ball valve 21 is closed, as shown in the figure. To do this, the shaft 25 leading through the housing 26 of the ball valve 21 is rotated using the handle 24. The shaft 25 in turn engages a spherical closing body 23 of the ball valve 21 and rotates this from an open to a closed position. In Fig. 2, the ball valve 21 and thus the spherical closing body 23 is shown in the closed position. The opening through the spherical closing body 27 is rotated out of alignment with the flow channel 3 and aligned transversely to it. The spherical surface of the closing body 23 seals the flow channel 3 in conjunction with the seals 31.

In order to apply the counterpressure required to reset the flow monitor 1 on the downstream side of the closing body 6, the screw plug 16 shown in Fig. 1 is removed from the thread 19 and an adapter piece 28 is screwed into the thread 19 instead. The adapter piece 28 has a through-channel 32 in its interior and is connected at a second end to a hose connection 29, to the side of which facing away from the adapter piece 28 a rubber bag air pump 30 is connected. With the help of the rubber bag air pump 30, a pressure can now be built up on the downstream side of the closing body 6 of the flow monitor 1 via the hose connection 29 and the through-channel 32 of the adapter piece 28.

If the pressure built up is high enough to overcome the counterpressure upstream of the closing body 6, the closing body 6 moves out of the

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The closing valve returns to the open position shown in Fig. 1, and the ball valve 21, which is closed to allow pressure to build up in the section 33 of the flow channel 3 located between the spherical closing body 23 and the closing body 6 of the flow monitor 1, can be opened again. The fluid line can now be operated in normal mode again. The adapter piece 28 can be removed from the thread 19 and the sealing plug 16 can be reinserted.

The embodiment shown is merely illustrative and is not restrictive. For example, the invention can be used for flow monitors in which the closing body is held in the open position by gravity rather than by a retaining force generated by a spring. Instead of the adjustment option for the trigger flow shown in the embodiment by means of an adjustment ring that engages in ring grooves, a thread can be provided in the section of the guide pin 8 in which the ring grooves 12a to 12c are arranged, as well as an adjustment nut that replaces the adjustment ring 11 and is guided on the thread. Other forms of fluid-tight closure of the opening through the housing are conceivable. In addition to the preferred use of the flow monitor as a gas flow monitor in gas line systems, the invention can also be used for flow monitors in liquid lines, for example water lines.

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bezupszeichenliste

1 Flow monitor 2 Housing 3 Flow channel 4 Flow direction 5 Valve seat 6 Locking body 7 poetry 8th Guide pin 9 Support element 10 Coil spring

11 Adjustment ring

12a to c ring groove

13 inner thread 14 External thread 15 Tap hole 16 Screw plug 17 poetry 18 renewal 19 thread 20 extension

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21 Ball valve 22 inner thread 23 Locking body 24 Handle 25 Wave 26 Housing 27 opening 28 Adapter piece 29 Hose connection 30 Rubber ball air pump 31 . Poetry 32 Through-channel 33 Section

Claims (9)

1. Flow monitor for automatically shutting off fluid-flowing lines when the fluid flow exceeds a defined maximum flow with - a housing ( 2 ) defining a flow channel ( 3 ) and having a valve seat ( 5 ) inside, and - a closing body ( 6 ) arranged in the housing ( 2 ), wherein the closing body ( 6 ) is held in a normal state by a retaining force in an open position in the flow direction ( 4 ) in front of the valve seat ( 5 ) and is moved against the valve seat ( 5 ) by a fluid flow exceeding the defined maximum flow in order to seal off a part of the flow monitor ( 1 ) that is fluidically downstream of the valve seat ( 5 ) from the fluid flow, marked by , - an opening ( 15 ) which is guided transversely to the flow channel ( 3 ) through the housing ( 2 ) and can be closed in a fluid-tight manner in a section of the housing ( 2 ) located behind the valve seat ( 5 ) as seen in the flow direction ( 4 ). 2. Flow monitor according to claim 1, characterized by a tap hole as opening ( 15 ). 3. Flow monitor according to one of claims 1 or 2, characterized in that the cross section of the opening ( 15 ) is substantially smaller than the cross section of the flow channel ( 3 ). 4. Flow monitor according to claim 3, characterized in that the ratio of the cross sections of the opening ( 15 ) and the flow channel ( 3 ) is 1:100 or less. 5. Flow monitor according to one of the preceding claims, characterized in that the opening ( 15 ) widens towards the outside of the housing and is provided with a connection structure ( 19 ) for connecting external components. 6. Flow monitor according to claim 5, characterized by a thread as a connection structure ( 19 ). 7. Flow switch according to claim 6, characterized by a screw plug ( 16 ) for closing the opening ( 15 ). 8. Flow monitor according to claim 7, characterized by a seal ( 17 ) arranged between the screw plug ( 16 ) and the housing ( 2 ) for fluid-tight sealing of the opening ( 15 ). 9. Flow monitor according to one of the preceding claims, characterized by a pin-like extension ( 20 ) of the housing ( 2 ) running transversely to the flow channel ( 3 ) in the region in which the opening ( 15 ) is passed through the housing ( 2 ).