CZ2009202A3 - Flow guard - Google Patents

Abstract

A flow monitor (2), in particular a gas flow monitor, for automatically closing the flowable fluid line is provided with at least one body (4) comprising a valve seat (20a, 20b) which defines a flow channel (6) extending from the first connection opening (8a). ) to the second connection opening (8b), with the closing body (26) movable within the body (4) relative to the valve seat (20a, 20b) and with a tensioning mechanism which acts on the arrangement of the closure body (26) arranged at a distance from the seat ( 20a, 20b) of the valve. A further valve seat (20a, 20b) is provided within the body (4), which is spaced along the flow channel (6) from the first valve seat (20a, 20b). The tensioning mechanism acts on a modified arrangement of the closure body (26) spaced from this further valve seat (20a, 20b). At least a partial abutment of the closure body (26) on one of the valve seats (20a, 20b) corresponds to the closed position. The arrangement of the closure body (26) spaced from the two valve seats (20a, 20b) corresponds to an open position.

Description

BACKGROUND OF THE INVENTION The invention relates to a flow monitor, in particular a gas flow monitor, for automatically closing a fluid flow line with at least one body comprising a valve seat defining a flow channel extending from the first connection port to the second connection port with a closing body movable therein relative to the seat and a tensioning mechanism which acts on the arrangement of the closure body spaced from the valve seat.

BACKGROUND OF THE INVENTION

For the purposes of the invention, the term conduit means any element of any shape and of any material through which a medium, in particular a liquid, for example a gas, can be guided. Such an element may, for example, be a pipe or pipe or part of a pipe or pipe. However, such an element can also be understood to mean a fitting or flowable device or a component thereof.

Flow monitors of the kind mentioned at the outset are known in the art. The flow monitor may be installed as a component in a conduit system, for example as a connecting piece between two gas or liquid conduits. The flow monitor serves to interrupt the flow of fluid through the conduit when the volumetric flow through the flow monitor exceeds a certain limit.

• · · · · · · · φ · • · φ · φ · φ ·

Typically, a tension coil spring that surrounds the pin is used as a tensioning mechanism, abutting one end on the abutment abutment and one end abutting the closure body or connected to the closure body. In the normal state, i.e. when the volumetric flow of a fluid, for example gas, does not exceed a predetermined limit value, the coil spring pushes the closure body away from the valve seat, so that a gap or opening remains between the valve seat, closure body and fluid may flow. However, if the volumetric flow limit is exceeded, the pressure exerted by the fluid on the closure body is sufficient to compress the coil spring and at least partially bring the closure body against the valve seat. As a result, the aforementioned gap or the aforementioned opening is closed and the fluid flow is virtually, or predominantly to the complete, interrupted. In principle, this condition remains as long as the pressure on the closure body is sufficient to compress the coil spring. However, if this pressure drops, the coil spring can be relieved, the closure body pushed out of its position in the valve seat and the gap or the opening reopened. The flow monitor can then flow again.

By a special design of the prior art flow controllers, for example by arranging the valve seat, the tensioning mechanism and the closure body, the preferred preferred flow direction in the flow controllers is predetermined. A preferred flow direction means that the flow monitor may only flow in one particular direction from the first port to the second port to be functional, i.e. to prevent fluid flow when a certain volume flow limit is exceeded. However, such flow detectors are not suitable for conduit systems which are basically not dimensioned for a particular flow direction or whose flow direction is, if necessary,

• · · · · «· · ·« · «· běž · * · * · * · * · * běž φ φ · běž běž běž · běž běž běž běž běž běž běž běž běž běž běž běž běž běž However, if a flow direction monitor with a preferred flow direction is used in the changing flow direction piping system, additional installation work is required on the flow monitor, such as replacing the flow monitor, each time the flow direction changes.

Furthermore, a fitter who intends to mount a flow monitor with a preferred flow direction must take into account a large number of flow monitors with different connecting pieces or connecting counterparts, for example threads for screw connection with arbitrary fittings such as pipes, in order to select a flow monitor flow fitting with a counterpart matching the fitting connection piece. The selection of a matching connection counter is additionally made more difficult by the preferred flow direction of the flow monitor, since the matching connection counterpart must be arranged on the right side of the flow monitor, i.e. the correct connection opening. However, this will result in higher logistical costs, since storage of different flow monitors is required.

SUMMARY OF THE INVENTION

Accordingly, it is a technical object of the invention to provide a flow monitor, in particular a gas flow monitor, which will not be limited to the preferred flow direction and thus provides flexible connection options.

This technical problem is solved by a flow monitor, in particular a gas flow monitor, for automatically closing the flowable medium conduit, with at least one body comprising a valve seat defining a flow channel extending from the first connection port to the second connection port, with the closing body movable within the body with respect to the valve seat and the tensioning mechanism acting on the closing arrangement. · · · · · · · φ · · · · φ · · · · · · · · · · · · · · · · · · · · A valve body having a distance from the first valve seat is provided inside the body, which is spaced apart from the first valve seat along the flow duct, the tensioning mechanism acting on the spaced arrangement of the closure member 1. from this further valve seat, wherein at least partial engagement of the closure body on one of the valve seats corresponds to the closed position, and wherein the arrangement of the closure body spaced from the two valve seats corresponds to the open position,

According to the invention, it has been found that a flow monitor with a preferred flow direction can be further improved simply by providing at least one additional valve seat within the body to a flow monitor without a preferred flow direction. Thus, the closure body may at least partially engage the first valve seat, but also the second valve seat, thereby interrupting the flow of fluid through the flow monitor when the predetermined volume flow limit is exceeded. The tensioning mechanism is designed in such a way that in both directions along the flow channel it can react to exceed the volumetric flow limit, but it can also guarantee the open position of the flow monitor, ie the arrangement of the closing body spaced from both the first valve seat and the second valve seat when the volumetric flow does not exceed the limit value.

In contrast to the preferred flow direction monitors, the flow monitor according to the invention has two closing positions. The first closing position is at least partially abutting the closing body on the first valve seat and can in principle be adopted only when the fluid flows through the flow monitor in one particular direction along the flow channel. The second closing position consists in at least partially engaging the closing body on the second valve seat and can in principle only be assumed when the fluid flows through the flow monitor in a direction along the flow channel opposite to the aforementioned flow direction. As a result, the open position of the flow monitor is always given when the closure body, possibly under the action of the tensioning mechanism, is in a position distant from both the first valve seat and the second valve seat.

The flow monitor according to the invention makes it possible to reduce the logistical costs to be incurred by the installer, since for a flow monitor without a preferred flow direction, the orientation of the flow monitor during installation, for example in conduit systems, is essentially irrelevant. Therefore, it is sufficient if the connection counter piece on one side of the flow monitor is adapted to the connection piece of the line system fitting which is adapted for connection. Advantageously, the flow meters according to the invention have connection pieces which differ from each other at their connection openings. In this way, the installer can reduce the number of flow monitors with different designs that he must have in stock, since he can confront the flow monitor with one particular connection piece of one armature, or simply rotate it and mount it on the armature if at least one side of the flow monitor has adapted counterpart for mounting on the fitting.

In a preferred embodiment of the flow monitor, a pin is provided inside the housing, which bears at least indirectly on the housing by means of at least one bearing, and at least one bearing element is arranged on the pin, the tensioning mechanism being supported on the pin and on the bearing element; the closure body is mounted on this pin movably along the flow channel. The pin can be arranged, for example, centrally or even coaxially inside the body. In principle, however, it is conceivable to arrange the pin within the housing, although it runs parallel to the axis of the housing or the axis of the flow channel, but not centrally. Furthermore, the pin arrangement parallel to the axis of the body can be deflected and instead the pin can be oriented relative to the axis of the body with a slope. The seating element can again function in particular as a support for the tensioning mechanism.

Furthermore, at least one further abutment element may be provided on the pin, spaced from the first abutment element along the flow channel, the tensioning mechanism being disposed in the region between the two abutment elements, and the closure body being movably arranged between the abutment elements.

In a further preferred embodiment of the flow monitor, an external thread or an internal thread is provided at least indirectly on the body in the region of the first connection opening and / or an internal thread or an external thread on the body in the region of the second connection opening. Indirectly arranged means that the body as such may be connected to an adapter which is inserted, for example by frictional engagement, into one of the connection openings or is mounted externally with a frictional connection on the body in the region of the connecting openings and in which the thread is formed. However, it is also possible not to use any adapter and to make the thread directly in the body material. The adapter may provide the advantage of replaceability, that is, optionally, the adapter provided with a certain thread may be removed and replaced with another adapter having a thread with properties different from the previously removed thread, for example a different thread pitch. In this way, the connecting pieces can be designed in a flexible and changeable manner. In particular, the screw thread further provides good compatibility with a large number of different fittings due to its standardization.

Preferably, an external thread is provided at least indirectly on the outer peripheral surface of the body in the region of the first connecting hole, and on the inner peripheral surface of the body in the region of the second connecting hole, an internal thread complementary to this external thread. Indirectly φ

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Furthermore, the flow channel preferably has an enlarged cross-section in the region between the two valve seats. This cross-section can be enlarged, for example, by a recess in a corresponding part of the body. In this way, it is possible to promote fluid flow in the open position of the flow monitor, since more space is available for the fluid to flow around the closure body arranged between the valve seats. The effects of dynamic pressure differences when flowing the closure body in the open position can thereby be compensated at least in part, preferably predominantly.

In a further preferred embodiment of the flow monitor, an adapter is provided inside the housing which comprises a valve seat and on which the pin receptacle is directly supported. By means of an adapter, for example, a prior art flow direction monitor can be retrofitted to a flow monitor without a preferred flow direction. However, the adapter also allows for flexible retrofitting of finished flow sensors by removing the insertable and removable adapter from its position inside the housing and replacing it with another adapter with different design features. It is possible to select an adapter with a substantially reduced flow cross-section when the flow monitor as a whole has a smaller flow cross-section. This exemplary variant is intended to illustrate the various possibilities of using the adapter.

• · φ · · * · φ · φ · φ · · φ · φ · φ · φ · φ ·

Furthermore, the at least one valve seat preferably comprises a groove or recess for receiving a sealing element, in particular an O-ring. In this way, it is possible to increase the sealing effect of the closure body at least partially abutting on one of the valve seats, so that the volumetric fluid flow through the flow monitor can be almost completely interrupted in the closed position. Advantageously, the shape and arrangement of the grooves or the recesses of the valve seats and the shape, arrangement and bearing of the closure body are matched to one another such that in the closed position the best possible sealing is achieved.

The pin may be at least indirectly supported by at least two spacers on the body spaced apart along the flow channel, indirectly supported means that these spacings need not be in direct contact with the body but rather be supported by a spacer, for example an adapter insertable into the body. However, direct support on the body is also possible. In this way, the mounting of the pin inside the body is stabilized. In contrast to the use of only one pin receptacle, which may however be sufficient, the second pin receptacle, spaced from the first receptacle, reduces the moment of force causing turbulent flowing fluid, which can lead to pin deflections or oscillations, to a portion of the pin, directly unsupported by a single save.

In a further preferred embodiment of the flow monitor, the bearing is designed as a ribbed disc, which with its outer peripheral surface abuts the body and / or the adapter and with its inner peripheral surface abuts the pin and / or one of the abutment elements.

The ribbed disc is preferably a disc whose shape is adapted to the inner contour of the body or the adapter provided in the body. For example, the ribbed disc may be a circular disc. The modified circular disk may have a central circular bore whose diameter is adapted to the outer diameter of at least one portion of the pin or one of the abutment members so that the corresponding portion of the pin or the abutment element may pass through the opening to support it. On the other hand, the overall diameter of the ribbed disc is advantageously matched in the corresponding parts to the inner diameter of the body or the adapter arranged inside the body. Provision may be made for the outer periphery of the fin plate to extend into grooves and / or recesses provided on the body or adapter to promote support stability. Between the outer periphery of the ribbed disc and the periphery of the central aperture there is at least one or more flow-through apertures in the aforementioned modified circular disc, which may have essentially any shape. These flow openings allow fluid to pass through the pin receptacles, in this case a modified circular disk, and thereby keep the flow monitor flowable even though the pin receptacle is in one particular example supported along the entire inner peripheral surface of the body or adapter. The zebra extend between these flow openings in a substantially radial direction.

Furthermore, the bearings can at least indirectly support the pin on the side of the area bounded by the abutment elements. In this way, a particularly stable arrangement of the pin within the body is achieved, since the lever arm of the pin portions not directly supported by the adapted bearings is thereby further reduced.

The tensioning mechanism may comprise a first resilient element disposed between the first abutment element and the closure body, in particular a coil spring, and a second resilient element disposed between the second abutment element and the closure body, in particular a coil. · · Pruž · · pruž pruž............... These resilient elements can utilize the abutment elements as abutment points, and thus as abutments, and abut the closure body from different sides or are connected to the abutment body, so that movement of the closure body along the flow channel has a direct influence on the degree of compression or extension. of these elastic elements. In principle, however, it is immaterial whether the elastic elements are elastic elements subjected to compression or tension. However, in the case of elastic elements subjected to tensile stress, these elastic elements must be connected to the closure body and the abutment elements, which is not necessary in the case of elastic elements subjected to compression.

It is particularly advantageous if the flow monitor tensioning mechanism is designed symmetrically. Designed symmetrically means that the volumetric flow limit values that result in the closure of the flow monitor are substantially, or even exactly, the same in both possible flow directions. Meanwhile, for example, two structurally identical elastic elements with identical elastic properties can be used. However, it is also conceivable to use structurally different elastic elements.

In this case, the closure of the flow monitor may be formed asymmetrically, i.e. the limit value of the volumetric fluid flow from which the flow monitor interrupts the fluid flow assumes a different value for the two possible different flow directions from the first connection port to the second connection port and vice versa.

However, the tensioning mechanism is not limited to the embodiment described above. Rather, the tensioning mechanism may comprise a single spring element, in particular a coil spring, arranged between the first abutment element and the second abutment element, which passes through, for example, one of its threads, an opening in the closure body. In this way, it is very easy to guarantee a symmetrical closing of the flow monitor, since by using a single spring element the properties of the spring element, for example the spring constant of the coil spring, are essentially the same for both possible flow directions. .

However, it is also possible that the tensioning mechanism comprises a single tension and compression spring disposed between one abutment element and the closure body. In this way, too, a symmetrical closure of the flow monitor can be guaranteed, since the movement of the closure body to the closure position is retained by the same single spring in both possible flow directions.

In a further preferred embodiment of the flow monitor, the pin may comprise at one end an external threaded portion, in particular an extension, wherein the external thread may cooperate by helical movement with one of the bearings, in particular one ribbed disc. In this way it is possible to change the position of the pin along the flow channel. In this way, it is also possible to change the position of the abutment elements arranged on the pin of the tensioning mechanism arranged on the pin and of the closing body movably mounted on the pin, especially in its rest position, i.e. when the volumetric fluid flow is not sufficient to cause the biasing mechanism. The closure of the flow monitor can also be varied by such a displacement of the pin, in particular for the purpose of an asymmetric closure procedure.

In addition to or alternatively to the pin extension, one of the abutment elements may comprise an external threaded portion, in particular an extension in which the pin is received, and wherein the outer thread may cooperate by helical movement with one of the bearings, in particular the rib disc. By means of this arrangement it is possible to change the position of the respective bearing element • · · · ··· ·· · ·

- · · · · · 2 ······················ φ along the flow duct, which, as mentioned above, may result in an altered or asymmetric closure of the flow monitor.

In a further preferred embodiment of the flow monitor, one of the abutment elements is connected to the pin, while the other abutment element comprises an opening in which the pin is movably mounted. In this way it is possible to change the arrangement of the pin along the flow duct without having to dispense with the advantageous support of the pin by means of two bearings.

There are a large number of possibilities for creating and further improving the flow monitor according to the invention. For this purpose reference is made both to claim 1 of the following claims and to a description of exemplary embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of one embodiment of the flow monitor of the present invention in the open position; FIG. 2 is a cross-sectional view of one embodiment of the flow monitor of the present invention in the first closed position; a sectional view of one embodiment of a flow monitor according to the invention in a second closed position.

DETAILED DESCRIPTION OF THE INVENTION

Giant. 1 shows a section through an exemplary flow monitor 2 according to the invention. The flow monitor body 4 defines a flow passage 6 and comprises two connection openings 8a, 8b between which the flow passage 6 extends. On the outer circumferential surface 10 of the body 4, in the region of the first, The connection hole 8a is formed in the body 4 by an external thread 12. On the inner circumferential surface 14 of the body 4 there is provided an external thread 12 in the housing 4. This embodiment of the flow monitor 2 with two mutually complementary threads 12, 16 in the connection holes 8a, 8b makes it easier for the installer to find the corresponding connection thread for the line connection (not shown). for example, for a threaded pipe. Since the orientation of the installation of the flow monitor 2 according to the invention is, as will be explained in greater detail below, in principle irrelevant, the installer can rely on having two different connection pieces with only one flow monitor 2. The number of flow detectors 2 with two different connection pieces kept in stock can therefore be reduced, in particular by half. The body 4 further comprises in the region of the second connection opening 8b. a flange projection 18 which provides good support when installing the flow monitor 2, for example when screwed onto a fitting (not shown).

However, it is also possible to equip the flow monitor 2 with the same connection pieces, for example with the same threads, in the region of the connection openings 8a, 8b. The advantageous feature of the lack of a preferred flow direction is not affected by this embodiment of the connection pieces or the combination of different connection pieces.

Inside this body 4, in this particular example, a first valve seat 20a is further provided, which comprises a recess 22 in cross-section in the form of a circular segment in which the first sealing element 24a, here the O-ring, is stably mounted. This sealing element 24a defines a sealing plane, that is, a plane in which the fluid flow is interrupted when the closure body 26 at least partially abuts the first sealing element 24a of the first valve seat 20a. However, the use of sealing element 24a, 24b is not necessary. Similarly, it may be sufficient to provide a valve seat 20a, 20b with only a bearing surface for the closure body 26 when the tightness requirements of the flow monitor 2 in the closure position are small. Between the female thread 16 disposed on the body 4 and the first valve seat 20a, the body 4 further comprises a groove 28 in which the outer rib 30 of the first rib 30 is arranged as a bearing.

In the region of the first connection opening 8a, an adapter 32 is housed within the body 4, for example by frictional contact. The adapter 32 comprises a recess 34 in the shape of a circular segment for receiving an additional sealing element 24b as well as an additional groove 36 as a save. The second valve seat 20b comprising the second sealing element 24b is therefore arranged in this special example on the adapter 32. The adapter 32 provides the advantage of interchangeability of the components associated with it. The need for such replacement may arise, for example, when components during operation of the flow monitor 2 are subject to wear greater than that of the housing 4. Furthermore, flow monitors with one preferred flow direction can be retrofitted to the flow monitor 2 without the preferred flow direction. of the invention. Between the first seat 20a. the valve body and valve seat 20b, i.e. in the region in which the closure body 26 can move along the flow passage 6, the body 4 comprises a radially outwardly directed recess 38. This recess 38 therefore provides more space for the fluid to flow around the closure body 26 in the open position. which helps to compensate for unwanted dynamic pressure differences.

The rib discs 30a, 30b disposed in the body 4 or adapter 32 are each mounted on their abutment 40a, 40b on the other side of the region, respectively on the other side of the region. * 4 4 · 4 · bounded by abutment elements 40a, 40b. and thus support the components of the flow monitor 2, which are located approximately centrally on the axis 42 of the body 4 or on the axis of the flow channel 6. Both bearing elements 40a, 40b have an annular reinforcement 44 on their outer circumferential surface which can serve as support for the tensioning mechanism. located between the abutment elements 40a, 40b. In this particular example, the first abutment element 40a includes an adapter 48 provided with an external thread 46. The first abutment element 40a further comprises a central bore extending along the flow channel 6 in which the pin 50 is received. the end of the pin 50 housed in the first abutment element 40a is threaded.

The first abutment element 40a and the pin 50 are connected to each other in this embodiment. The outer thread 46 of the extension 48 of the first abutment element 40a and the inner circumference of the second fin disc 30b are adapted to engage one another. It is thus possible to move or adjust the first bearing element 40a and the pin 50 associated therewith by a helical movement relative to the second fin plate 30b along the flow channel 6. In the exemplary embodiment of the guard

2, the inner circumference of the second fin disc 30b extends into one thread of the external thread 46 adjacent the reinforcement 44 of the first abutment element 40a. As a result, the position of the first abutment element 40a, and hence the pin 50, can be shifted, as shown in FIG. 1, by up to five individual turns of the external thread 46 in the direction of the second abutment element 40b. The second abutment element 40b is also retained by the first fin disc 30a and includes a central bore extending along the flow passage 6 which extends through the other end of the pin 50. The pin 50 is not movably connected to the second abutment element 40b in this special example. · · · · · · E e e e

I η ······ ημ · · · ··· »········ φφ φφφ φ * φ ·· ·· · saved. In this way, the pin 50 can be adjusted along the flow channel 6.

Between the two abutment elements 40a, 40b. and in particular between the two sealing elements 24a, 24b of the seats 20a. 20b of the valve, the closure body 26 is mounted on the pin 50 movably along the flow channel 6. In the example shown in Fig. 1, the closure body 26 occupies a central position. The shape of the closure body 26 is in this case both symmetrical along the flow channel 6 and perpendicular thereto. In this way, homogeneous closure can be guaranteed regardless of the actual direction of fluid flow. In cross-section, the closure body 26 is formed as a combination of two T-shaped components, the upper T-parts being arranged directly on the pin 50.

Between the abutment elements 40a. 40b and one coil spring 52a, 52b is provided on both sides on both sides under pressure. The coil springs 52a, 52b surround the pin 50 and partially the abutment elements 40a, 40b. In this case, the coil springs 52a, 52b are structurally identical and have substantially identical properties. This, together with the arrangement of the abutment elements 40a, 40b, which always have the same distance along the flow duct 6 from the valve seat 20a, 20b closest to them, guarantees a symmetrical closing behavior of the flow monitor 2. The valve seats 20a, 20b ultimately determine the maximum displacement of the closure body 26 and hence the maximum deflection of the coil springs 52a, 52b.

Two tension springs may also be used instead of the compression springs 52a, 52b. In this case, the coil springs would have to be connected to the abutment elements 40a, 40b and the closure body 26. Alternatively, instead of two springs, one spring could be used, which is mounted between the two abutment elements 40a, 40b and one of its threads passes through an opening (not shown) in the closure body 26. In a further alternative, a single coil spring loaded a pressure which is connected to one of the abutment elements 40a. 40b and on one side with the closure body 26, wherein the arrangement of the closure body 26 in the unloaded state of the coil spring is preferably centrally between the two valve seats 20a, 20b along the flow duct 6. Such an arrangement would result in a substantially symmetrical closing behavior of the flow monitor 2.

Giant. 2 shows an example of the embodiment known from FIG. 1, when the flow monitor 2 is flowing through the fluid in one particular direction, see arrow 54, with a volumetric flow greater than a predetermined limit value. The pressure exerted by the fluid on the closure body 26 is sufficient to compress the second coil spring 52b so that the closure body 26 of the peripheral surface portion 56 abuts the first sealing element 24a, thereby taking the first closing position. As a result, the fluid flow is virtually, preferably, completely interrupted. However, it is naturally possible to form the valve seats 20a, 20b without recesses 22, 34 and without the sealing element 24a, 24b with only the contact surface and instead to provide the sealing body 26 with at least one sealing element on the outer circumference.

In the embodiment shown in Figure 2, the coil springs 52a, 52b are not coupled to the closure body 26. By engaging the closure body 26 on the first valve seat 20a, the first coil spring 52a is spaced from the closure body 26 and is in a virtually lightened state. However, it is also conceivable to connect the coil springs 52a, 52b to the closure body 26. In this case, the first coil spring 52a in the state of the flow monitor 2 shown in FIG. 2 would be subjected to tension and could therefore also affect the flow monitor 2 behavior. closure, since in addition to the work required to compress the second coil spring 52b, the fluid would be fluid. Flowing through flow monitor 2 still had to do the work necessary to extend the first coil spring 52a. The limit of the volumetric flow can therefore be increased compared to the arrangement of the coil springs 52a,

52b stressed to a pressure not connected to the closure body 26.

Giant. Fig. 3 shows an example of the embodiment known from Figs. 1 and 2, when the flow monitor 2 is flowing through the fluid in the second direction, see arrow 54, the volume flow of which is sufficient to cause the valve body 26 to close the valve seat 20b containing the sealing element 24b. . Thus, in the state shown in FIG. 3, the closure body 26 occupies a second possible closure position. By means of this example it is explained how a flow monitor 2 can be formed without a preferred flow direction. The flow monitor 2 can therefore be used very flexibly in different mounting and flow conditions.

Claims (15)

1. A flow monitor (2), in particular a gas flow monitor, for automatically closing a fluid flow line; - with at least one body (4) comprising a valve seat (20a, 20b) defining a flow passage (6) extending from the first connection port (8a) to the second connection port (8b), - with a closing body (26) movable within said body (4) relative to the valve seat (20a, 20b), and - with a tensioning mechanism acting on the arrangement of the closure body (26) spaced from the valve seat (20a, 20b), characterized in that: - a further valve seat (20a, 20b) is arranged inside the body (4), which is spaced from the first valve seat (20a, 20b) along the flow duct (6), - wherein the tensioning mechanism acts on the spaced arrangement of the closure body (26) and from this further valve seat (20a, 20b), - wherein the at least partial abutment of the closure body (26) on one of the valve seats (20a, 20b) corresponds to the closed position, and - wherein the arrangement of the closure body (26) spaced from the two valve seats (20a, 20b) corresponds to the open position. Flow monitor (2) according to claim 1, characterized in that: - a pin (50) is arranged inside the body (4) and is supported at least indirectly on the body (4) by at least one bearing (30a, 30b), - at least one abutment element (40a, 40b) provided on the pin (50) is provided, - the tensioning mechanism is mounted on the pin (50) and on the abutment element (40a, 40b), and that the tensioning mechanism (40a, 40b) · * 9 9 * 9 9 * 9 · ·· · - the closure body (26) is mounted on the pin (50) movably along the flow channel (6). Flow monitor (2) according to claim 2, characterized in that: - at least one further abutment element (40a, 40b) is provided, which is arranged on the pin (50) at a distance along the flow channel (6), the tensioning mechanism is disposed in the region between the two abutment elements (40a, 40b) and that - the closing body (26) is movably mounted between the abutment elements (40a, 40b). Flow monitor (2) according to one of Claims 1 to 3, characterized in that an external thread (12) or an internal thread (16) is arranged at least indirectly on the body (4) in the region of the first connection opening (8a) and / or or an internal thread (16) or an external thread (12) is arranged at least indirectly on the body (4) in the region of the second connection opening (8b). Flow monitor (2) according to claim 4, characterized in that an external thread (12) is arranged at least indirectly on the outer circumferential surface (10) of the body (4) of the first connection opening (8a) and on the inner circumferential surface (14). The internal thread (16) complementary to the external thread (12) is arranged at least indirectly in the region of the second connection opening (8b) of the body (4). Flow monitor (2) according to one of Claims 2 to 5, characterized in that an adapter (32) is provided inside the body (4), which comprises a valve seat (20b) and on which the pin receptacle (50) is directly supported. . · · · · · · · Φ · φ · · · · φ · • · ΦΦ · ΦΦ · ΦΦ · ΦΦ · Flow monitor (2) according to one of Claims 2 to 6, characterized in that the pin (50) is supported on the body (4) at least indirectly by at least two bearings arranged at a distance from one another along the flow channel (6). Flow monitor (2) according to one of Claims 2 to 7, characterized in that the bearing is designed as a ribbed disc (30a, 30b), which bears on its outer peripheral surface on the body (4) and / or on the adapter (32). ) and its inner circumferential surface abuts the pin (50) and / or one of the abutment elements (40a, 40b). Flow monitor (2) according to one of Claims 3 to 8, characterized in that the bearings support at least indirectly the pin (50) on the other side of the area bounded by the abutment elements (40a, 40b). Flow monitor (2) according to one of Claims 3 to 9, characterized in that the tensioning mechanism comprises a first spring element, in particular a coil spring (52a) arranged between the first bearing element (40a) and the closing body (26), and a second spring element (40b), in particular a coil spring (52b) disposed between the second abutment element (40b) and the closure body (26). Flow monitor (2) according to one of Claims 3 to 9, characterized in that the tensioning mechanism comprises a single spring element, in particular a coil spring, arranged between the first abutment element (40a) and the second abutment element (40b) passing through the opening. in the closing body (26), for example by one of its threads. Flow monitor (2) according to one of Claims 3 to 9, characterized in that the tensioning mechanism comprises a single mechanismus φ φ φ φ v φ φ φ φ A spring loaded on tension and compression, arranged between the first abutment element (40a) and the second abutment element (40b). Flow monitor (2) according to one of Claims 2 to 12, characterized in that the pin (50) comprises at one end an external threaded part, in particular an extension, wherein the external thread can cooperate by helical movement with one of the bearings, in particular with rib disc (30a, 30b). Flow monitor (2) according to one of Claims 2 to 13, characterized in that one of the abutment elements (40a, 40b) comprises a male threaded part (46), in particular an extension (48) in which the pin (2) is received. 50), and wherein the external thread (46) can cooperate by helical movement with one of the bearings, in particular the rib disc (30a, 30b). Flow monitor (2) according to one of Claims 3 to 14, characterized in that one of the abutment elements (40a, 40b) is connected to the pin (50), while the other abutment element (40a, 40b) comprises an aperture, wherein the pin (50) is movably mounted.