DE102007008285B4 - Flow monitor and corresponding connection arrangement - Google Patents

Abstract

Flow monitor (1), in particular gas flow monitor, for automatically shutting off a line through which a medium can flow, - with a flow channel (2) through which the medium can flow in a flow direction (S), - with a housing (2) surrounding the flow channel (2) 2), and - with a shut-off body (5), which is movably mounted in the flow channel (2) relative to the valve seat (4) between an open position and a closed position, characterized in that in the housing as a means (6) for increasing the Flow velocity of the medium flowing in the flow channel (2) a cross-sectional reduction of the flow channel is provided, in which the cross section of the flow channel is reduced by 10 to 50%.

Description

The present invention relates to a flow monitor, in particular gas flow monitor, for automatically shutting off a flow-through medium, with a flow channel, which is flowed through by the medium in a flow direction, with a flow channel enclosing housing having a valve seat in the flow channel, and with a shut-off body which is movably mounted in the flow channel relative to the valve seat between an open position and a closed position. Furthermore, the invention relates to a corresponding connection arrangement with a medium permeable by a medium line and with a line connected to the flow monitor, in particular gas flow monitor. Such a flow switch and a corresponding connection arrangement is from the DE 10 2004 041 499 B4 known.

By the term line is meant in the context of the invention any element of any shape and of any material through which a medium, in particular a fluid, for example a gas, can be passed therethrough. Such an element can be for example a pipe or a pipe or a component of a pipe or a pipe. By such an element may also be meant a fitting or a device through which it can flow or a component thereof.

Flow monitors, which are used in of a medium, in particular a fluid, such as a gas, through-flow lines, especially in pipes or the associated fittings and equipment, are known in a variety of designs. They serve to interrupt the supply of the medium at an impermissible flow rate increase of the medium above a predetermined value. This occurs especially when due to damage to the piping system, the flow of the medium increases excessively. At normal constant maximum flow rates, for example, due to a gas load operated at full load, however, the flow switch is not triggered.

A connectable with a line flow switch is for example from the German utility model DE 201 16 899 U1 known. Here, a shut-off body is mounted on a guide pin under bias, wherein the shut-off body is movable relative to a valve seat against the bias of an open position into a closed position. If the flow switch normally located in open position triggered at an inadmissible increase in flow, so the shut-off moves in the flow direction against a spring force on the valve seat until the shut-off is sealingly connected to the valve seat and thereby shuts off the line.

A problem with a flow switch according to the prior art is that due to the relatively high weight of the shut-off the flow switch is limited in its installed position. Thus, in a horizontal installation position, ie in which the flow channel is perpendicular to the direction of gravitational force, a flow monitor has a characteristic closing factor. If, however, the flow switch is arranged in a position other than horizontal, in extreme cases in a vertical installation position in which the flow channel is parallel to the direction of gravitational force, the closing factor changes due to the gravitational force acting on the shut-off element. The change of the closing factor with respect to the horizontal mounting position is dependent inter alia on the weight of the shut-off and the degree of deviation from the horizontal mounting position.

A flow switch is often designed for horizontal application, with the appropriate closing factor the relevant provisions of the German Association of Gas and Water e. V. (DVGW). Since changes due to the dead weight of the shut-off of the closing factor at a deviating from the horizontal mounting position mounting positions corresponding to a certain angle deviating mounting positions are usually not allowed, unless you accept the change in the closing factor and thus possibly associated security risk.

In accordance with the regulations of the DVGW, certain flow switches are also designed for other mounting positions, in particular vertical mounting positions. However, this complicates the warehousing and logistics and increases the space required for storage, since different flow monitors are to be stored for different mounting positions.

From the DE 10 2004 006 632 A1 Furthermore, a check valve is known.

It is therefore an object of the present invention to develop a flow monitor of the type mentioned in such a way that it can be mounted independently of position in a corresponding connection arrangement.

The previously derived and indicated object is achieved in that in a flow switch of the type mentioned in the housing as a means for increasing the flow velocity of the flow channel flowing medium, a cross-sectional reduction of the flow channel is provided, in which the cross-section of the flow channel is reduced by 10 to 50%.

At the same time acting on the shut-off bias can be increased so much that the weight of the shut-off against the thus increased switching signal is negligible. In other words, compared to the prior art, according to the invention, the switching signal, ie the force triggering the flow switch on the shut-off, amplified by increasing the flow rate so that the weight of the shut-off in comparison to the switching signal is small. If the shut-off body is arranged in a region of increased flow velocity, preferably at a position at which the flow velocity reaches a maximum value, this will cause the flow switch to switch earlier, ie be more sensitive.

The spring constant of the spring, which exerts the bias on the shut-off body in the open position and which serves for switching point adjustment, is preferably to be chosen so that the influence of the weight of the shut-off on the flow monitor is negligible. So that the weight of the shut-off can be neglected, has proved to be advantageous if the ratio of the weight (in g) of the shut-off - this can be made of plastic and, for example, have a weight of 0.5 to 1.5 g - to the spring constant ( in N / mm) of a shut-off spring in the open position under bias holding spring is less than 200, in particular between 70 and 160, and preferably between 100 and 110.

According to one embodiment of the flow monitor according to the invention, the means is designed and / or arranged such that it increases the flow velocity at least immediately before the shut-off body, relative to the flow direction.

Preferably, the means for increasing the flow velocity before the shut-off, with respect to the flow direction, arranged. In particular, the means is a cross-sectional reduction of the flow channel, wherein the cross-section of the flow channel is preferably reduced by 20 to 50%. According to a particularly preferred embodiment, the means is a nozzle.

The means, in particular the nozzle, in particular has an outlet which faces the shut-off body. In this way an optimal flow of the shut-off is achieved.

According to a further embodiment of the flow monitor according to the invention, the nozzle is cone-shaped. A cone-shaped design leads to a homogeneous and largely vortex-free flow in and downstream of the nozzle.

In order to further optimize the flow, it is provided according to a further embodiment that the longitudinal central axis of the cross-section reduction, in particular nozzle, extends coaxially to the longitudinal central axis of the shut-off body.

According to yet another embodiment, the distance between the outlet and with respect to the flow direction front surface of the shut-off in the open position is selected so that the front surface is disposed at a position in the flow channel at which the flow rate reaches a maximum value. In this way, the sensitivity of the flow monitor is further increased.

A reduction in the dimensions of the flow monitor and thus a space-saving design is achieved in that, according to yet another embodiment of the flow monitor according to the invention, the means for increasing the flow rate is arranged in the interior of the housing. In this case, the production of the flow monitor is simplified in that the means, such as the nozzle, is integral with the housing, so the housing and the flow rate increasing means form a one-piece component.

The object is further achieved in a connection arrangement of the type mentioned above in that the flow monitor is designed as described above. In particular, in such a connection arrangement, the flow channel is parallel to the direction of gravitational force. Alternatively, it is also conceivable that the flow channel extends at an angle, in particular perpendicular, to the gravitational force.

There are now a variety of ways to design and further develop the flow monitor according to the invention and the connection arrangement according to the invention. For this purpose, for example, referenced on the one hand to the claims subordinate to claim 1, on the other hand to the description of an embodiment in conjunction with the drawing. In the drawing shows:

1 a sectional view of an embodiment of a flow switch according to the invention in the open position, and

2 a sectional view of the flow switch off 1 in closed position.

1 shows an embodiment of a flow monitor 1 in accordance with the present invention in the open position. The flow switch 1 is used for automatic shut-off of a medium through which a medium can flow. Essential features of the flow monitor 1 are a flow channel 2 , which can be traversed by the medium in a flow direction S, a flow channel 2 enclosing housing 3 that has a valve seat 4 in the flow channel 2 has, and a shut-off 5 in the flow channel 2 relative to the valve seat 4 between said open position and one in 2 shown closed position is movably mounted.

In the present embodiment of a flow monitor 1 it is a gas flow monitor designed to carry, for example, natural gas with a density ratio of 0.64 or gaseous liquid gas with a density ratio of 1.2 as the medium. The following on the basis of 1 and 2 flow switch described in more detail 1 is particularly suitable for flow velocities of 2 to 10 m / s (these values apply at the inlet of the flow switch).

To amplify the switching signal or the force required for switching, is a means 6 for increasing the flow velocity of the flow channel 2 provided flowing medium. The middle 6 , which is a cross-section reduction 7 in the form of a nozzle 8th is, is formed and in the flow channel 2 arranged that the flow rate immediately in front of the shut-off 5 , with respect to the flow direction S, is increased.

As the 1 and 2 show is the nozzle 8th in front of the shut-off body 5 , with respect to the flow direction S, arranged, wherein the longitudinal center axis of the nozzle 8th coaxial with the longitudinal central axis of the shut-off body 5 runs.

Further, the distance between the outlet 9 the nozzle 8th and the front surface with respect to the flow direction 10 of the shut-off 5 in the open position ( 1 ) so chosen that the front surface 10 is disposed at a position in the flow channel at which the flow velocity reaches a maximum value. Im in 1 As shown, this position is approximately halfway between the outlet 9 and valve seat 4 , But there are also designs of the flow monitor 1 conceivable in which the means 6 , in particular the nozzle 8th is formed and / or arranged such that the position in which the flow velocity reaches a maximum value closer to the valve seat 4 as at the outlet 9 lies or vice versa.

As advantageous for the application of the flow switch for gases with a density ratio between 0.5 and 1.5 has at flow rates of 2 to 10 m / s (at the inlet of the flow switch) a nozzle proved, which has a cone-shaped wall, the opposite wall surfaces are employed at an angle of 50 to 70 ° relative to each other. The nozzle preferably causes a reduction of the cross section of the flow channel by 50 to 70%. If the shut-off body is then arranged in the region of the highest flow velocity, the force on the shut-off body increases significantly.

Will now the spring constant (spring rate) at the shut-off 5 in open position under bias holding spring, here the helical compression spring 11 Increased accordingly over the prior art and adapted to the inventive increase in the flow velocity, it is thereby achieved that by the weight of the shut-off 5 Conditional weight force in the case of a non-horizontal arrangement of the flow switch 1 becomes negligible. In other words, compared to the prior art, on the one hand, in the area of the shut-off body 5 in the open position increases the flow velocity and on the other hand, the spring constant of the spring 11 , which serves to switch point adjustment, increased accordingly, so is the switching signal, that is, the switching of the shut-off 5 triggering force, so high that the weight forces of the shut-off can be neglected.

In the advantageous application of the flow switch described above for gases having a density ratio of between 0.5 and 1.5, a spring constant in a range of 0.004 to 0.009 N / mm, preferably 0.005 to 0.008 N / mm, has proven particularly suitable preferably 0.006 N / mm, whereby a self-weight of the shut-off of 0.5 to 1.5 g is negligible at flow rates of 2 to 10 m / s (at the inlet of the flow switch) and a previously trained and arranged nozzle. The ratio of the shut-off body weight (in g) to the spring constant (in N / mm) is in particular less than 200, is preferably between 70 and 160 and is particularly preferably about 100.

The flow switch according to the invention is for the first time position-independent, so it can be mounted in any angle relative to the direction of gravity in a corresponding connection arrangement.

Claims (14)

Flow monitor ( 1 ), in particular gas flow monitor, for the automatic shut-off of a medium-flowable line, - with a flow channel ( 2 ), which can be traversed by the medium in a flow direction (S), - with a flow channel ( 2 ) enclosing housing ( 2 ), which has a valve seat ( 4 ) in the flow channel ( 2 ), and - with a shut-off body ( 5 ) in the flow channel ( 2 ) relative to the valve seat ( 4 ) is movably mounted between an open position and a closed position, characterized in that in the housing as a means ( 6 ) for increasing the flow velocity of the flow channel ( 2 ) flowing medium, a cross-sectional reduction of the flow channel is provided, in which the cross-section of the flow channel is reduced by 10 to 50%. Flow monitor ( 1 ) according to claim 1, characterized in that the means ( 6 ) is designed and / or arranged such that the means ( 6 ) the flow velocity at least immediately before the shut-off body ( 5 ), relative to the flow direction (S), increased. Flow monitor ( 1 ) according to claim 1 or 2, characterized in that the means ( 6 ) in front of the shut-off body ( 5 ), With respect to the flow direction (S), is arranged. Flow monitor ( 1 ) according to one of the preceding claims, characterized in that the means ( 6 ) a cross-section reduction ( 7 ) of the flow channel ( 2 ), wherein the cross-section of the flow channel ( 2 ) is preferably reduced by 20 to 50%. Flow monitor ( 1 ) according to claim 4, characterized in that the means ( 6 ) a nozzle ( 8th ). Flow monitor ( 1 ) according to one of the preceding claims, characterized in that the means ( 6 ), in particular the nozzle ( 8th ), one to the shut-off ( 5 ) pointing outlet ( 9 ) Has. Flow monitor ( 1 ) according to claim 5 or 6, characterized in that the nozzle ( 8th ) is cone-shaped. Flow monitor ( 1 ) according to one of claims 4 to 7, characterized in that the longitudinal central axis of the cross-section reduction ( 8th ), in particular the nozzle, coaxial with the longitudinal central axis of the shut-off body ( 5 ) runs. Flow monitor ( 1 ) according to one of claims 5 to 8, characterized in that the distance between the outlet ( 9 ) and with respect to the flow direction (S) front surfaces ( 10 ) of the shut-off body ( 5 ) is selected in the open position so that the front surface ( 10 ) at a position in the flow channel ( 2 ) is arranged, at which the flow velocity reaches a maximum value. Flow monitor ( 1 ) according to one of the preceding claims, characterized in that the ratio of the weight (in g) of the shut-off body ( 5 ) to the spring constant (in N / mm) of the shut-off ( 5 ) in the open position under prestressing spring ( 11 ) is less than 200, in particular between 70 and 160, and preferably between 100 and 110. Flow monitor ( 1 ) according to one of the preceding claims, characterized in that the means ( 6 ) inside the housing ( 3 ) is arranged and in particular in one piece with the housing ( 3 ) is executed. Connection arrangement with a medium-flowable line and with a line connected to the flow monitor ( 1 ), in particular gas flow monitor, characterized in that the flow switch ( 1 ) is designed according to one of the preceding claims. Connecting arrangement according to claim 12, characterized in that the flow channel ( 2 ) runs parallel to the direction of gravitational force. Connecting arrangement according to claim 12, characterized in that the flow channel ( 2 ) is angular, in particular perpendicular, to the direction of gravitational force.

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