FI104126B - Arrangement for monitoring, measuring and / or detecting flows, in particular leaks, in piping - Google Patents

Description

104126

Arrangements for monitoring, measuring and / or indicating flow, especially leakage in pipeline system Järjestely virtausten, erityisesti vuotojen valvontaan, mittaukseen ja / tai osoittamiseen putkistossa 5 according to the preamble of claim 1.

The present invention relates in particular to a leakage indicator with the aid of which it is possible to monitor, measure and / or indicate a flow in a pipe or pipe system. With the help of the arrangement, damage caused by leakage can be minimized and unnecessary consumption is detected at an early stage.

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Prior art leakage indicating arrangements include several valves, special in: ': volume flow meters, actuators for stop valves and / or components which are often sensitive to contaminants in the flowing agent, such as the water. of II «· <'' 'a quite complicated set are the expensive, and these arrangements also have the

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The disadvantage is that their sealing force is low when the valve is closed and. #t flow resistance high during flow.

The object of the invention is to obtain a monitoring, measurement and / or indication of flow with a valve that has a large sealing force when the valve is • · •. closed and minimal flow resistance during flow. This is mainly achieved by holding the valve closed with the permanent magnet or magnets, so that the force that closes the valve closed is greatest when there is no flow and the force to close the valve decreases with increasing flow due to the magnet pulling force 2 104126 the distance of the magnet from the magnetic material or a magnet of opposite polarity increases.

The features of the invention emerge from the appended claims.

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The invention and the properties obtained by this are described in the following with reference to the accompanying drawings, which schematically illustrate various embodiments of the invention.

Figure 1 in cross-section an embodiment of the invention where a magnetic coupling pours the valve closed.

Figure 2 front view of a detail of Figure 1.

Figure 3 shows another embodiment where a magnetic coupling pours the valve closed.

Figure 4 shows a detail of the embodiment of Figure 3, where the valve is poured:; '; open.

: Y: Figure 5 shows a pipe system with the arrangement according to the invention.

I · • «« t · ·! Figures 6a and 6b show in cross section a further embodiment according to the invention whereby, by means of a resilient expandable space,

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• I 'j' produces a flow pulse when the valve opens.

Figure 7 shows in cross-section yet another embodiment according to the invention where f: ··! a flow pulse is obtained by means of an elastically expandable space in the valve «· :: 20.

Figure 8 shows in cross-section a detail of Figure 7.

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Figures 9 and 10 show various embodiments of resilient and elastically expandable spaces.

The arrangement according to the invention comprises (see Figs. 1, 3, 6a, 6b and 7) a valve housing 8 with valve seat 9 and a valve body 3 which is tightly connected to the valve seat and 5 means for forcing the valve body 3 and the valve seat 9 towards each other with a force exceeding the force with which a certain predetermined pressure difference across the valve seat strives to release the valve body 3 from it. The means comprise at least one magnet 1 adjacent to the valve body 3 and / or the valve seat 9 with a closed position pulling force exceeding said force and which in the open position strives 10 to drive the valve body 3 and the valve seat 9 back towards each other only as the flow through the valve seat 9 stopped or decreased to a predetermined value.

A pipeline with an arrangement according to the invention is shown in Figure 5. The liquid or gas is conducted from the main conduit 26 through the valve 16 to a supply line 25 through a meter 17 and arrangement according to the invention, the valve housing 8, an indicator / measuring unit 27 and the stop valve 29, to consumption. .

When the valve in the arrangement of Figures 1 and 2 is in the closed position and the pressure difference between the inlet 15 and the outlet 20 increases due to minimal flow on the outlet side, the flexible intermediate wall 10 and the valve seat 9 connected to the intermediate wall against the outlet 20 and the valve body 3 follow. with the magnetic coupling 20 closed. The magnetic coupling is between magnet 1 or magnets 1 connected or connected to the valve body 3 and magnetically actuated parts 2 of the valve seat. Displacement of the valve body toward the outlet 20 is counteracted by a spring 7 and the displacement of the valve seat against the outlet 20 by another spring 6. As the pressure difference increases further, the magnetic coupling is opened and the spring 7 pulls the valve body 25 back towards the inlet 15 while further pushing the intermediate wall 10 and the valve seat 9 toward the outlet 20 and the valve opens. When valve body 3 and valve seat 9 are separated, the indicator 5 is activated and the lamp 27 lights up. When the flow stops or decreases to a predetermined value, the spring 6 pushes the valve seat back toward the valve body 3 and the magnetic coupling is re-formed and the valve is closed.

When the valve in the arrangement of Figures 3 and 4 is in the closed position and the pressure difference between the inlet 15 and the outlet 20 increases, the flexible partition 10 and the valve seat 9 which is connected to the partition wall are pressed against the outlet 20.

The valve body 3 follows and the magnetic coupling between them is closed.

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The magnetic coupling is between the magnet 1 which is connected by a spindle to the valve body 3 and magnetically actuated parts 2 of the valve seat 9. The displacement of the valve body into the valve seat 9 is counteracted by a spring 7 and the displacement of the valve seat against the outlet 20 by another spring 6. When the pressure difference increases further, the magnetic coupling is opened and the valve body 3 is pushed into the valve seat against the spring 7 while the flexible partition 10 and the valve seat 9 are pushed back against the inlet 15 of the spring 6. When the valve body 3 is moved into the valve seat 9, the valve body 3 is no longer pressed against the seal. 4 on the valve seat 9.

The seal 4 may also be located on the valve body 3. When valve body 3 and V. in valve seat 9 are separated, the indicator 5 'is activated and the lamp 27 lights up. In this arrangement, a new magnetic coupling between the magnet 1 and a resilient 23 secures 21 when the valve is opened, ensuring that it is fully opened. Then the flow,,; terminating or declining to a predetermined value opens the springs 7, 23 r e * ['.

The magnetic coupling between the magnet 1 and the bracket 21, the spring 7 pushes in the valve body 3 against the annular elastic seal 4 on the valve seat 9 and • · · • * ·! the magnetic coupling between the magnet 1 and the valve seat 9 eats is formed and the valve Γ · · · is closed.

A third arrangement is shown in Figures 6a and 6b. In this arrangement, a valve according to the invention is used in conjunction with a flow meter 17 and a resilient or elastic one. expandable space, a pulsator 19. With this arrangement, small flows can be measured that are not normally measured by a meter based on the minimum movement of the liquid or gas in the direction of flow at small flows.

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In the meter showing all the flows, a meter having an encoder or some other device used for remote reading of the meter can also indicate leakage in a pipe system and thereby act as a leak alarm.

At minimal flows in the third air arrangement according to Figures 6a and 6b when the flow meter does not react normally, the flow cannot pass through the meter 17 when the valve is closed (Fig. 6a) but the flow is forced to pass through a shunt pipe 18 to the pulse 19. the bellows 13 against the spring 12. As the bellows 13 is pressed out against the seat 14 (Fig. 6b), the pressure of the valve being poured closed by permanent ring magnets 1, 2 increases. One ring magnet 1 is mounted on a spindle attached to the valve body 3, the other ring magnet 2 is attached to the holder 11. When the valve is closed, the valve body 3 is pressed against the annular elastic seal 4 so that the valve is fully closed. Since the pulling force of the magnets 1, 2 no longer can withstand the pressure from the inlet 15, the magnetic coupling between the magnets 1, 2 and thus the valve (Fig. 6b) is opened. When, valve body 3 and valve seat 9 are separated, the indicator 5 'is activated (Fig. 6b). The liquid or gas, which is collected in the pulse atom 19, is pressed through the meter 17 on the basis of the edema 12 of the force 12 which pushes back the bellows 13, which is possible because the pulling force I r between the magnets 1, 2 In this way, a total amount of liquid or gas flows through the meter 17, indicating this.

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The magnet 1 or the magnets 1, 2 can be elastic or resiliently fixed in the * * in • · · *. valve body 3 and / or valve seat 9 so that the valve can act as a check valve and thereby close the valve by allowing valve seat 9 to be pushed backwards against the seal 4 without being stopped by the magnet 2 on the holder 11.

The valve (Fig. 3) can also be used alone in such a way that the valve seat 9 is tightly connected in a pipe so that the liquid or gas can only pass the valve when the valve body 3 is opened by the inlet pressure and flow flows past the valve body 3 .

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The intermediate wall 10 and the bracket 21 and the spring 6 are removed there. The valve can then act as a check valve and simple flow sensor.

In arrangements according to the third embodiment of Figures 6a and 6b, the pulse atom can be designed in different ways. The liquid or gas can be collected by a pulsator 19 within the valve (Fig. 7) or by various means in a separate pulsator 19 (Figs. 6a, 6b, 9 and 10).

The valve with built-in pulsator 19 (Fig. 7) functions in the same way as the valve in the previous arrangement according to Figs. 6a and 6b. An elastic hose 13 is secured tightly at its two ends to the cylindrical valve so that the liquid or gas is contained. Liquid or gas can flow in and out of the inlet 15 of the valve through the heel 30 of the tube 24 and into the pulse 19. Liquid or gas can also flow in and out to the outside of the hose 13 and into the shunt pipe 18 after the meter 17.

At minimal flows in the arrangement with built-in pulsator (Fig. 7), the valve is closed and the flow is controlled through the heel 30 in the tube 24 and extends the hose 13 (Fig. 8). Where the hose 13 has expanded so much that the force to expand the hose 13 is further

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| Greater than the pulling force of the magnets 1, 2, which keeps the valve closed, is opened; the valve and flow flow through the meter 17 indicating the flow. The flow «lii · • · ..... flows out further into the tube 24 and also into the shunt tube 18 and further to the outside of the hose 13. The hose 13 pulls together as the pressure difference between the inlet 15 and the outlet 20 reduces. When the flow decreases sufficiently, the spring 7 presses the valve body 3 against the inlet 15 until the magnets 1, 2 approach

Ml v 1 each so much that they close the magnetic coupling and the valve is closed. As long as a minimum flow of 9 9 in 1 ·· is continued, the expansion and discharge of the pulse atom 19 is repeated as the · • · · · · · · valve is alternately opened and closed. If the flow through the valve increases, the valve "": ": is poured open and the hose 13 assumes an equilibrium position and contractes when the flow stops.

Two embodiments in addition to that described above (Figs. 6a and 6b) by different pulsators 19 are shown in Figures 9 and 10.1 one (Fig. 9), the bellows of the pulse 19 is an elastic hose 13 'on a tube. 24 within pulse 19. Hose 13 'is tightly secured with both ends of the tube 24, but can be expanded therebetween if the pressure at the inlet 15 penetrates liquid or gas through the heel 30 of the tube 24 to the inside of the tube 13'. In the other (Fig. 10), the expandable space is limited within the pulse atom 19 by a piston 13 "with seals 31 which are actuated by a spring 12 which pushes back the piston 13" when the valve opens.

The valve can also be a solenoid valve that is controlled by electric current and is affected by pressure difference before and after the valve or can be time controlled and open after a certain time or via some contact which is actuated by a bellows such as e.g. hoses 13 '.

The described embodiments (Figs. 1-4, 6a, 6b and 7) all have a solenoid valve. This allows the use of magnetic indicator or indicators 5, 5 'which are affected by the movement of the magnet or magnets and can be activated when valve body 3 and valve seat 9 are separated. Also other ways to indicate that valve body 3 and valve seat 9 are separable can be used. Repeated short • ;;; Activation indicates minimal flow and / or leakage. Long activation indicates

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flow.

• · · «· · III ·« IMII • ·. ·. -. The above described embodiments are examples of different ways of realizing one. arrangement according to the invention. However, the invention encompasses all embodiments of the invention characterized by the appended claims.

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Claims (10)

Arrangement for monitoring, measuring and / or detecting flows, in particular leaks, in a piping system comprising a valve body (8), a valve seat (9) and a valve seat (3) closely connected to a 5 seat, and means for a valve seat (3) and valve seat (9) ) forcing against each other with a force that exceeds the force by which a predetermined pressure difference across the valve seat (9) tends to detach the valve body (3) from the valve seat (9), characterized in that said members comprise at least one valve body (3); or a magnet (1) fitted to the valve seat (9) having a tensile force 10 in the closed state which exceeds said force and which in open state tends to pull the valve seat (3) and the valve seat (9) back against each other only when the valve seat ( 9) has been stopped or reduced to a predetermined value. An arrangement according to claim 1, characterized in that said members also comprise one or more resilient or resilient elements (6, 7) disposed between one or more valve bodies (8), the valve seat (9) and / or the valve body (3) acting in concert therewith. ) to ensure that the valve housing (3); returns against the valve seat (9) when the flow has stopped or decreased to 20 at a predetermined value. Arrangement according to Claim 1 or 2, characterized in that said means further comprise one or more valve body (8) and valve seat (9) acting in concert therewith and / or valve body and valve body (3). / 25 elastic or flexible element (10, 21, 23) arranged to ensure that the valve opens fully when said pressure difference is exceeded and the valve remains open until the flow through the valve • · • «: m” socket has decreased to at least a predetermined value. e <. 1 (1 Arrangement according to Claim 1, 2 or 3, characterized in that the valve seat (9) is connected to the valve body (8) by means of a flexible partition (10), e.g. a diaphragm or bellows, which divides the valve body into the inlet and the outlet. 104 126 wherein the valve housing (3) is resiliently (7) connected to the valve body (8) on the ground side so that the valve housing (3) is followed with the valve seat (9) when the differential pressure valve body (8) the inlet and increases the output side, but detaches and returns when said predetermined pressure difference is exceeded, and also that the valve seat (9) is resiliently (6) connected to the valve body (8) such that the valve seat (9) returns and closes against the valve body (3) the flow is reduced to at least a predetermined value. Arrangement according to Claim 1, 2 or 3, characterized in that the valve body (8) is divided by the valve seat (9) into the inlet and outlet side, the valve seat (3) being resiliently pressed against the outlet (7) by the valve seat (9). ) while acting as a non-return valve. Arrangement according to Claim 5, characterized in that the valve seat 15 (9) is connected to the valve body (8) by means of a flexible partition (10), e.g. a diaphragm or bellows, wherein the valve body (3) is flexibly connected to the valve body. (8) the outlet side such that the valve housing (3) is followed with the valve seat (9) when the differential pressure valve body (8) the inlet and increases the output side, but released when the said predetermined pressure difference is exceeded, and that the valve the seat (9) is lithically 20 (6) connected to the valve body (8) such that the valve seat (9) is then retracted and the valve body (3) and the valve body (8) are provided with a flexible (23) III magnetic switch (21), which prevents the valve body (3) from returning until the flow of,., T has decreased to at least a predetermined value. • · · Ml • · «I · I Arrangement according to any one of the preceding claims, in connection with the flow meter (17) in the pipeline, characterized by a flexible or resiliently expandable space • · (28) at the inlet side of the valve body (8) to provide a flow pulse • · ' • * I I I I I I I I I Arrangement according to claim 7, characterized by a parallel pipe (18) past a flow meter (17) and a valve body (8) closed in said space (28) such that a pressure difference across the valve body (8) provides a corresponding pressure to the space. 104126 π An arrangement according to claim 7 or 8, characterized in that the expandable space (28) is a flexible bellows (13), a hose (13 ') or a spring-loaded (12) piston (13'). 5 Arrangement for detecting flows or leaks according to any one of the preceding claims, characterized by a detector (5, 5 ') mounted on or over the valve body (8), which is influenced or engaged by the valve housing (3) and the valve seat (3). 9) resign. 10 • II <II • I β · <«· • ·« «, * • · *« · '«t · • f ·« · p • «· f · 1 • · ·« · · · · «« «· F <1 *» * • «« · • · ^^ • 9 • 9 • I * • • · i IIT «· t • <