DE10202067A1 - Safety stop valve for gas pipe has spring-loaded flat plate which remains in open position with gas flow below threshold value and moves to closed position if flow exceeds threshold - Google Patents

Abstract

The stop valve (1) has a flange (6) which fits in the gap between two sections of pipe (2,2'). It has a cylindrical outer surface (8) in contact with the inside of the upstream pipe, with a groove (10) accommodating a sealing ring (12). It has a conical valve seat (36) against which the valve disk (24) may be forced by the drag caused by the gas flow (32). The valve disk has a sealing ring (26) at its edge. A spider (33) supports a cylinder containing a spring surrounding a central rod (16) supporting the disk. The spring is compressed as the disk moves toward the valve seat.

Description

The present invention relates to a gas flow monitor and a method of manufacturing the gas flow switch. The gas flow switch essentially comprises one cylindrical valve body, the at least one Through opening for flowing through the gas flow switch Has gas, and one axially displaceable in the valve body guided and essentially transverse to one through the Arranged valve body passing gas flow Shut-off. The shut-off body can, for example, as a plate, formed as a cone, as a piston or as a ball his. The shut-off body is between a sealing position, in which the shut-off body rests on a valve seat and closes the or each through opening in a gastight manner, and a flow position in which the shut-off body from the Valve seat is lifted and the or each through opening releases, movable.

The gas flow monitor also includes one Shutters assigned to the first stop, the Valve body associated second stop and between the two stops arranged elastically deformable Holding means. The holding means practice one of the gas flow opposing force on the shut-off body, the Distance between the two stops in the axial direction Framework of the manufacture of the gas flow switch set becomes. The distance setting is used to calibrate the Gas flow monitor for a predeterminable nominal flow, at with the shut-off valve in the flow position, and / or a predefinable closing flow, in which the shut-off body is in the sealing position.

Such gas flow monitors are different Designs known from the prior art. You will be in Gas lines from gas-conducting systems installed and found as Use safety devices around the gas flows through the Limit gas lines to maximum values. The Gas flow monitors are for a specifiable nominal flow, where the shut-off valve is in the flow position located, designed. At about 10% to 30% above the The nominal flow rate is the closing flow rate Shut-off body moved into the sealing position and the appropriate gas line shut off. Becomes a gas pipe System manipulated inadmissibly, e.g. B. by unintentional Exposing a gas line to the facility can leak gas. The escaping gas is in the vicinity of the exit point a significant risk to the environment and a source of danger for Living beings. Upstream of the exit points Gas flow monitors interrupt the at their installation location Gas flow as soon as inadmissibly high gas volume flows (in the area of the closing flow) can be reached.

Under the name Mertik-Maxitrol is from DE 43 44 575 A1 a gas flow monitor from Maxitrol, 23555 Telegraph Road, Southfield, Michigan 48037, USA known as the One Valve body and a valve insert that can be used therein having. The valve insert includes guide means through which a disc-shaped shut-off body between one Flow position and a sealing position slidable is led. The shut-off is by a pressure spring trained holding element held in the flow position.

The compression springs have very large tolerances, their Cause in the material used for the compression spring and the Have manufacturing processes. The tolerances of the compression springs are much larger than the tolerances allowed Excess flow valve. In spite of these tolerances Compression springs to ensure that a Gas flow monitors for a given nominal flow rate too is actually open and at a given Closing flow actually closes, everyone has to individual gas flow monitors calibrated after manufacture become.

When calibrating a gas flow switch, one is shown the gas flow simulates the force acting on the shut-off body and the compression spring between the first and the second Preloaded that the resulting spring force of the simulated force holds the scales so that the shut - off body is in the flow position (for calibration to a given Nominal flow) or in the sealing position (for calibration on a predetermined closing flow) is maintained. The The compression spring is preloaded by varying the distance between the first and the second stop. This takes place in the prior art such that at least one the two stops axially by means of an adjusting screw is movable. The adjustment screw must be around its longitudinal axis be rotated to an axial position of the stop adjust. If the desired axial position of the Stop is set, the adjusting screw must be against Twist backed up by what in the prior art Paint or glue is done. In the state of the art that is Calibrate a gas flow switch as part of the Manufacturing process very time and labor intensive.

In addition, the valve insert includes the known Gas flow switch on both sides of the shut-off body Guide means. This will ensure good management of the Shut-off body allows relative to the valve body. However, it is disadvantageous that the known gas flow monitor this makes it very large and bulky. An assembly of the Valve insert in areas that are difficult to access, e.g. in Angles or curves of pipelines, is with the known gas flow monitor is not possible.

FireBag are also automatic thermal safety devices known to the applicant, with which an inflow of gas in gas-conducting systems is not in Dependence of the gas flow, but depending on the temperature can be prevented. Once an allowable Limit temperature is exceeded, closes the known Safety device and interrupts the supply of gas the downstream gas-conducting system. This allows Explosions in the event of fire can be prevented. The Limit temperature is around 100 ° C. The well-known Safety precaution can also be very high term Loads of over 900 ° C for at least one hour get abandoned. To a gas pipe system both regarding excessive temperatures as well as regarding To be able to protect excessive flows has previously been a requirement Gas flow monitor and a thermal safety device be arranged one behind the other.

The present invention is based on the object Gas flow monitor of the type mentioned above to design and train that he is particularly quick and is easy to manufacture.

To achieve this object, the invention proposes starting from the manufacturing process of the type mentioned above that to set the nominal flow the maximum distance of the two stops to each other in the flow position and / or the maximum distance for setting the closing flow of the two stops to each other in the sealing position of a clamp fit is limited.

The gas flow monitor is according to the invention Manufacturing process fully assembled, the Flow position or the sealing position of the shut-off body has not yet been specified. To the gas flow switch calibrated to a predeterminable nominal flow first determines which setting force with the Nominal flow through the valve body flowing gas on the Shuts off in the axial direction. The shut-off body is brought into the flow position. The holding means are loaded with the setting force, for example by a of the two stops between which the holding means are clamped, the adjusting force is applied. This changes the distance between the two Stops and the relative position of the shut-off body to the Stop that is subjected to the adjusting force. Then is the maximum distance between the two stops by means of a clamp seat in the set position limited.

The two stops are relative during calibration freely movable in relation to each other in order to adjust the To allow nominal flow. At the end of the calibration the distance is then determined such that the holding means have the desired preload. The attacks will be at least in that axial direction which limits the maximum distance between the stops becomes. The minimum distance is determined by the between the Limits acting holding means limited. The clamp seat has the advantage that it is simple and quick can be manufactured and on the other hand a safe and allows reliable setting of the stops to each other.

The gas flow monitor can also be opened in a corresponding manner a predetermined closing flow can be calibrated by the shut-off body is held in the sealing position. It will the setting force determined with the closing flow gas flowing through the valve body onto the shut-off body in exerts axial direction.

There are different types of gas flow monitors conceivable. The designs differ in particular in the Type of guidance of the shut-off body in the valve body. According to A first design is the shut-off body with a pin connected in a pin receptacle of a valve insert of the valve body is guided axially. The first Stop is on the pin and the second stop on the Pen receptacle trained. There are holding means provided act between the stops and counter the shut-off the one acting on the shut-off body by the gas flow Push the force into the flow position.

• - der Absperrkörper wird in die Durchflussstellung bzw. in die Dichtstellung gebracht;
• - eine Einstellkraft wird ermittelt, die der Kraft entspricht, die bei Nenndurchfluss bzw. bei Schließdurchfluss durch die Gasströmung in axialer Richtung auf den Absperrkörper wirkt;
• - der erste Anschlag wird in Strömungsrichtung des Gases mit der Einstellkraft beaufschlagt; und
• - eine sich zwischen dem ersten Anschlag und dem Absperrkörper einstellende maximale Relativposition wird mittels Klemmsitz begrenzt.

According to an advantageous development of the present invention, a manufacturing method is proposed for such a gas flow monitor, which is characterized by the following method steps:

• - The shut-off body is brought into the flow position or in the sealing position;
• an adjusting force is determined which corresponds to the force which acts on the shut-off body in the axial direction at the nominal flow or at the closing flow through the gas flow;
• - The first stop is applied in the flow direction of the gas with the adjusting force; and
• - A maximum relative position established between the first stop and the shut-off body is limited by means of a clamp fit.

According to another design, there is a gas flow monitor conceivable in which a pin receptacle of a valve insert Valve body is connected to a pin on which the Shut-off body is guided axially. The first Stop is on the pin and the second stop on the Pen receptacle trained. There are holding means provided act between the stops and counter the shut-off the one acting on the shut-off body by the gas flow Push the force into the flow position.

• - der Absperrkörper wird in die Durchlassstellung bzw. in die Dichtstellung gebracht;
• - eine Einstellkraft wird ermittelt, die der Kraft entspricht, die bei Nenndurchfluss bzw. bei Schließdurchfluss durch die Gasströmung in axialer Richtung auf den Absperrkörper wirkt;
• - der zweite Anschlag wird entgegen der Strömungsrichtung des Gases mit der Einstellkraft beaufschlagt; und
• - eine sich zwischen dem zweiten Anschlag und dem Ventilkörper einstellende maximale Relativposition wird mittels Klemmsitz begrenzt.

According to another advantageous development of the present invention, a manufacturing method is proposed for such a gas flow monitor, which is characterized by the following method steps:

• - The shut-off body is brought into the open position or in the sealing position;
• an adjusting force is determined which corresponds to the force which acts on the shut-off body in the axial direction at the nominal flow or at the closing flow through the gas flow;
• - The second stop is acted against the direction of flow of the gas with the adjusting force; and
• - A maximum relative position established between the second stop and the valve body is limited by means of a clamp fit.

According to a preferred embodiment of the present Invention is proposed that the first stop or second stop using weights or using a Actuating element with the determined setting force becomes.

The setting force is advantageously dependent on the later installation position of the gas flow monitor. This means that if the axis of movement of the shut-off body runs vertically, must be determined by the weight of the Shut-off force caused in addition to that Spring force and the force of the gas flow on the shut-off body is taken into account, depending on the direction of movement of the Shut-off body with different signs. The Setting force for calibrating the gas flow monitor selected larger or smaller accordingly.

According to another advantageous development of the first Design of the present invention proposes that the first stop in between the first stop and the shut-off set relative position on the Shut-off body is attached using a clamp seat. For the second Design of the present invention proposes that the second stop in between the second stop and the relative position of the valve body at the Valve body is attached using a clamp.

For the first design of an invention Gas flow monitor is particularly proposed that the first stop on an extending in the axial direction Pin is formed axially in the valve body is slidably guided and when the first one is applied Stop with the adjusting force relative to that in the Flow position or sealing position Shut-off body is moved, and the resulting maximum relative position between the first stop and the Shut-off body with the help of an additional clamping element is limited, the clamping element by means of a clamp seat one viewed from the shut-off body at the first stop opposite side of the pin is attached. By the additional clamping element is the maximum distance between limited to the attacks. The two stops are using the holding means in their maximum distance from each other crowded.

For the second design of an inventive Gas flow monitor is particularly proposed that the second stop on one in the axial direction extending pin is formed on which the shut-off body is guided axially displaceably and when the second stop with the adjusting force relative to the Valve body is moved, and the resulting maximum relative position between the second stop and the Valve body with the help of an additional clamping element is limited, the clamping element by means of a clamp seat one viewed from the valve body the second stop opposite side of the pin is attached.

As a further solution to the object of the present invention it is suggested that a maximum distance between the two Stops to each other is limited by means of a clamp fit. Due to the press fit is the invention Gas flow monitor particularly easy and quick to manufacture. In addition, the clamp connection is reliable, resilient and almost impossible to solve. An unnoticed, unintentional Adjustment of an already calibrated gas flow monitor can almost be excluded.

According to an advantageous development of the present Invention is proposed for a first design that the Shut-off body by means of a clamp seat on the first stop is attached. In particular, it is proposed that in the Gas flow monitor arranged a pin axially is, the first stop at a first end of the pin trained and at the opposite end of the Shut-off body is clamped.

Alternatively, for a second design, it is proposed that the valve body by means of a clamp fit on the second Stop is attached. The second attack stands with itself radially outwardly extending pin receiving elements in Connection. These are in turn with the valve body Connection. The press fit can be between the second Stop and the pin receiving elements as well as between the Be pin receiving elements and the valve body.

For the first design, according to a preferred one Embodiment of the present invention proposed that Guide means for guiding the shut-off body in the Valve bodies are provided, the guide means being part of a valve insert, which by means of a press fit the valve body is attached. The press fit enables one easy installation of the valve insert in the valve body and is formed by the valve insert on a Circumference limit has a larger outer diameter than an end surface formed on the inside of the valve body. This makes assembly particularly easy by pushing and pushing the valve insert into the Valve body allows and reliable and stable durable connection created.

The valve body advantageously has one Stop area up to which the valve insert in the Valve body is inserted and on which the valve insert is applied. The valve insert with the Guide means in its axial position with respect to the valve body established. The stroke range of the Shut-off body between the flow position and the Sealing position defined. It therefore makes sense to have one exactly defined relative position between valve insert and valve body to accomplish. This is due to the stop area described reached.

For the first design, it is proposed that guide means provided for guiding the shut-off body in the valve body are, wherein the guide means comprise a pin receptacle, in which is the pin attached to the shut-off body axially is slidably guided, the pin receptacle in the axial Direction viewed only on one side of the Shut-off body is arranged. Through this arrangement of Guide means and the shut-off body becomes a special simple construction of the valve insert created, the only consists of essentially four components, namely the Pen receptacle, the pen, the shut-off body and the Holding means. Other components, for example to form a second Pin receptacle on the other side of the shut-off body not mandatory. The structure is particularly compact and enables the gas flow monitor according to the invention even in hard-to-reach areas of a gas-conducting System, such as in curved pipes, can be used well is. Furthermore, the valve insert can first in one Test specimen used and for its faultless function be checked before inserting into the valve body.

It is further suggested that the pin in the Pin holder at least two in the axial direction to each other spaced guide areas is guided. The least double guidance at spaced locations allows the pen to be guided in such a way that a precise Closing and opening, d. H. a precise shift of the Shut-off body between the flow and the sealing position is made possible. It also ensures that the Shutoff body in the sealing position always on the entire surface Valve seat in the valve body comes into contact. The Leadership areas can be in only one component, e.g. B. the Pen receptacle to be provided. The multiple leadership prevents the pen from tilting in the pen holder takes place and stick-slip effects may occur.

The pin is advantageously connected to the shut-off body a clamp seat attached.

For the second design, it is proposed that guide means provided for guiding the shut-off body in the valve body are, wherein the guide means comprise a pin receptacle, in which the pin is attached to, on which the shut-off body is guided axially displaceable, the pin receptacle in axial direction viewed only on one side of the Shut-off body is arranged. With this embodiment of the Invention becomes an even simpler construction of the valve insert created. The pin is advantageously in the Pin receptacle by a clamp fit on the valve body attached. The shut-off body is guided on the pin and can, for example, tilting of the shut-off body on the pin to avoid getting yourself in the axial direction of the pin particularly far-reaching shut-off guide area exhibit. This makes it possible, despite a simple structure the valve insert of the gas flow monitor according to the invention to enable reliable guidance of the shut-off body.

According to a further preferred embodiment of the invention it is proposed that the pin receptacle in the axial direction viewed on a side opposite the valve seat the shut-off body is arranged. This can make a special short valve insert can be realized. Through the described geometric arrangement it is easier to the valve insert even in pipes that are difficult to access insert gas-carrying system into the valve body.

The holding means can by the choice of material, for example. an elastomer, its elastically deformable properties receive. You can also use a get appropriate shape. These are advantageously Holding means as a spring element, preferably as one Coil spring, trained.

The spring element is preferably a compression spring educated. Compression springs have proven to be robust and reliable construction elements for a variety of Applications proved. They are inexpensive and can be made from any material, for example metal or Plastic are made. For use in one Gas flow monitors are dimensions and spring characteristics to take into account accordingly. The selection of the The spring constant of the compression spring depends on which one Gas flow values of the shut-off bodies up to their sealing position should be moved and how long the stroke of the shut-off body between the flow and the sealing position. In the Selection of the material of the compression spring is also on appropriate media resistance or temperature resistance respect, think highly of.

According to another advantageous development of the The present invention proposes that the Holding means act temperature-dependent, the of which Holding means exerted on the shut-off and the Gas flow opposite force when exceeding one Predeterminable limit temperature drops steeply. Preferably falls the force exerted by the holding means after exceeding the limit temperature drops to zero. With this training is a combination of gas flow switch and thermal Safety device realizable. The Temperature dependency of the holding means can, for example achieved that the holding means when reaching the Limit their physical cohesion by melting to lose. The holding means can, for example, as a compression spring be formed from metal, plastic or a other material that exists when the Limit temperature is melting. When the holding means melt, will the shut-off body no longer counteracts the gas flow supported, but one-sided by the flow forces applied. This has a shifting of the shut-off the flow position into the sealing position.

This gas flow monitor is also used to set the Closing flow is the maximum distance between the two stops to each other in the sealing position by means of a clamp fit limited. The combination of gas flow switch and thermal safety device has the specified Advantages, however, even without these characteristics of the license plate Claim 1. The present invention is therefore intended also on gas flow monitors of the latter type relate to which in the characterizing part of claim 1 mentioned features are missing.

According to a preferred embodiment of the invention, the temperature-dependent holding means from a eutectic Metal alloy formed. This has the main advantage that an alloy can be used on the one hand by using suitable components an elasticity of Holding means and on the other hand a melting of the holding means can achieve at a predetermined limit temperature. The Transition from the solid to the liquid phase takes place at eutectic metal alloys simultaneously for everyone Alloy components. Thus, the physical cohesion of the holding material safe and reliably at the specified limit temperature.

According to a further preferred embodiment of the The present invention proposes that the Valve insert comprises at least two components between which temperature-dependent lubricants are introduced, the Lubricant below a specifiable limit temperature inhibit axial displacement of the components relative to each other and above the limit temperature the displaceability of the Allow components relative to each other. The pen holder consists, for example, of two components which are interposed by one Lubricant are firmly connected. at The limit temperature of the lubricant is exceeded destroyed by the compound created and the two parts of the pin receptacle are in the axial direction freely movable relative to each other. As a result, the Shut-off body together with part of the pin holder from which due to the gas flow on the shut-off body acting force axially shifted into the sealing position. On separate actuating element to the shut-off body in the It is not necessary to move the sealing position. Should however, it may be desirable to be able to do just that by too high Temperatures in the area of the gas flow monitor the same takes place, an additional actuator be provided that the shut-off in the sealing position emotional. Such an actuator is, for example, as one Compression spring trained.

Further advantageous refinements and details of Invention can be found in the following description in which the invention with reference to that shown in the drawing Exemplary embodiments are described and explained in more detail. It demonstrate:

Fig. 1 is a longitudinal section of a gas flow monitor according to the invention in a first embodiment in a flow position;

FIG. 2 shows a view corresponding to FIG. 1 of a gas flow monitor in a sealing position;

3 shows a longitudinal section of a gas flow monitor according to the invention in a second embodiment in a flow position.

FIG. 4 shows a detail X from FIG. 3;

5 shows a longitudinal section of a gas flow monitor according to the invention in a third embodiment in a flow position.

Figure 5a is a perspective sectional view of the gas flow monitor of Figures 1 and 2..;

FIG. 6 shows a detail Y from FIG. 5;

7 is a longitudinal section of a gas flow monitor according to the invention in a fourth embodiment in a flow position.

FIG. 8 shows an illustration of a gas flow monitor according to FIG. 7 in a sealing position assumed when the gas flow is excessive; FIG. and

FIG. 9 is an illustration of a gas flow monitor according to FIG. 7 in a sealing position assumed at an excessive temperature.

In Figs. 1, 2 and 5a, an inventive gas flow control valve is designated according to a first embodiment in its entirety by reference numeral 1. The gas flow monitor 1 is inserted between two pipe sections 2 , 2 'of a pipe of a gas-conducting system. The gas flow monitor 1 comprises a valve body 4 which has a collar 6 which serves as a stop surface for the end faces at the ends of the pipe sections 2 , 2 '. The valve body 4 also has a cylindrical outer surface 8 with a recess 10 for receiving an annular seal 12 .

To assemble the gas flow monitor 1 , the valve body 4 is first inserted into the first pipe section 2 of the pipeline. The pipe section 2 , the valve body 4 and the second pipe section 2 'are then connected to one another, for example by welding, in the region of the collar 6 of the valve body 4 .

A valve insert is inserted into the interior of the valve body 4 . This can already be inserted during the assembly of the valve body 4 between the pipe sections 2 , 2 'or can also be inserted into the valve body 4 subsequently. The valve insert comprises a pin receptacle 14 with a pin guide area 16 which has an interior 18 . In the interior 18 , a pin 20 and holding means 22 designed as a compression spring are arranged axially displaceably. A shut-off body 24 with a seal 26 is fastened to the pin 20 . The holding means 22 are clamped between a first stop 44 assigned to the shut-off body 24 (via the pin 20 ) and a second stop 45 assigned to the valve body 4 (via the pin receptacle 14 ).

The pin receptacle 14 is arranged axially to a longitudinal axis 30 of the valve body 4 and extends in the radial direction up to a receiving surface 28 on an inner circumferential surface 34 of the valve body 4 . The pin receptacle 14 is fixed in the valve body 4 by means of a press fit. When installing the gas flow monitor 1 , the pin receptacle 14 is inserted into the valve body 4 until, viewed in the direction of insertion, a front surface of the pin receptacle 14 comes to rest on a stop area 50 of the valve body 4 (cf. FIG. 4).

The gas flow switch 1 shown in Fig. 1 is located in a flow position, the shut-off means 24 is arranged such that a passage of gas through the gas flow control valve 1 is possible. Arrows 32 indicate the gas flow. The gas can first flow through passage openings 33 provided in the pin receptacle 14 and then pass through an annular region formed between the inner peripheral surface 34 of the valve body 4 and the seal 26 of the shut-off body 24 . The gas can then flow past a contact surface formed in the valve body 4 , which serves as a valve seat 36 for the shut-off body 24 , and finally reach a through opening 38 of the valve body 4 . The gas can thus flow through the pipeline from the pipe section 2 into the pipe section 2 '.

FIG. 2 shows the gas flow monitor 1 from FIG. 1, the shut-off body 24 assuming a sealing position and resting with its seal 26 on the valve seat 36 over the entire surface. The inflowing gas represented by arrows 40 impinges on an impact surface 42 of the shut-off body 24 and generates a force directed in the direction B. A spring force of the holding means 22 directed in the direction A is opposed to this force. If the force B exceeds the force A, the shut-off body 24 , as shown in FIG. 2, is pressed against the valve seat 36 . The seal 26 comes to a gas-tight contact with the valve seat 36 .

The gas flow monitor 1 is first completely assembled using the manufacturing method according to the invention, the flow position or the sealing position of the shut-off body 24 not being precisely defined yet. In order to calibrate the gas flow monitor 1 to a predeterminable nominal flow, it is first determined which force exerts gas in the axial direction on the shut-off body 24 which flows through the valve body 4 with the nominal flow. This force is used as the setting force for calibrating the gas flow monitor 1 . The shut-off body 24 is brought into the flow position ( FIG. 1). The holding means 22 are acted upon by the adjusting force, for example by applying the adjusting force to the first stop 44 . This changes the distance between the two stops 44 , 45 and the relative position of the shut-off body 24 to the stop 44 . The maximum distance between the two stops 44 , 45 from one another is then limited by means of a clamp seat in the set position. For this purpose, the shut-off body 24 can simply be clamped onto the pin 20 . Alternatively, however, an additional clamping element 25 shown in dashed lines can also be clamped on the pin 20 , the shut-off body 24 still being freely displaceable on the pin 20 . The maximum distance between the two stops 44 , 45 from one another is limited by this clamping element 25 . The shut-off body 24 is always pressed against the clamping element 25 by the force B, even if the shut-off body 24 leaves the flow position and moves away from the pin receptacle 14 .

The shut-off body 24 can be moved freely on the pin 20 during the calibration. The two stops 44 , 45 are thus also freely movable relative to one another. This makes it particularly easy to set the nominal flow. At the end of the calibration, the shut-off body 24 is fixed on the pin 20 or the distance between the stops 44 , 45 is then determined in such a way that the holding means 22 have the desired pretension. The clamp seat has the advantage that it can be manufactured simply and quickly on the one hand and on the other hand enables the shut-off body 24 to be securely and reliably fixed on the pin 20 .

In a corresponding manner, the gas flow monitor 1 can also be calibrated to a predetermined closing flow rate by holding the shut-off body 24 in the sealing position. The setting force is determined which exerts gas flowing through the valve body 4 on the shut-off body 24 in the axial direction with the closing flow. The resulting distance between the stops 44 , 45 is determined by means of a clamp fit.

Fig. 3 shows a second embodiment of a gas flow monitor 1 according to the invention. In contrast to the gas flow monitor 1 from FIGS. 1 and 2, the pin 20 in the second embodiment is fastened in the pin receptacle 14 by means of a clamp seat and the shut-off body 24 is arranged on the pin 20 so as to be axially displaceable. The shut-off body 24 has a guide region 27 which extends in the axial direction beyond the shut-off body 24 and by means of which the mounting of the shut-off body 24 on the pin 20 is improved. The first stop 44 is formed by a stop surface of the shut-off body 24 . The second stop 45 is formed at one end of the pin 20 . The holding means 22 are clamped between the shut-off body 24 and the second stop 45 . The gas flow monitor shown in FIG. 3 functions analogously to the gas flow monitor 1 shown in FIGS . 1 and 2 and is moved from a flow position I by a stroke H into a sealing position II when a permissible gas flow value is exceeded.

In order to calibrate the gas flow monitor 1 according to the second embodiment to a predeterminable nominal flow, the shut-off body 24 is brought into the flow position. The holding means 22 are acted upon by the adjusting force, for example by applying the adjusting force to the second stop 45 . This changes the distance between the two stops 44 , 45 and the relative position of the valve body 4 to the stop 45 , since the pin 20 is axially displaced in the pin receptacle 14 . Then the pin 20 is clamped in the position due to the adjusting force in the pin receptacle 14 . As a result, the maximum distance between the two stops 44 , 45 from one another is fixed in the set position by means of a clamp fit.

Alternatively, an additional clamping element 25 shown in phantom of the pin 20 can be clamped on an extension 20 ', the pin 20 in the pin receptacle 14 is still freely movable. The maximum distance between the two stops 44 , 45 from one another is limited by this clamping element 25 . A force generated by the gas flow acts on the shut-off body 24 and via the holding element 22 , the second stop 45 and the pin 20 on the clamping element 25 and urges it against the valve body 4 or the pin receptacle 14 , even if the shut-off body 24 leaves the flow position and moves away from the pin receptacle 14 .

The pin 20 is freely displaceable in the pin receptacle 14 during the calibration. The two stops 44 , 45 are thus also freely movable relative to one another. This makes it particularly easy to set the nominal flow. At the end of the calibration, the pin 20 is fixed in the pin receptacle 14 or the distance between the stops 44 , 45 in such a way that the holding means 22 have the desired pretension.

FIG. 4 shows a detail X from FIG. 3. An end region of the valve body 4 is shown, in which the stop region 50 is provided on the inner peripheral surface 34 . The stop area 50 serves to axially fix the pin receptacle 14 in the valve body 4 . The pin receptacle 14 has an annular elevation area 52 , which comes into contact with the stop area 50 when the pin receptacle 14 is inserted. In a contact area 54 , the pin receptacle 14 with a cylindrical outer surface 56 is inserted into the valve body 4 by means of a press fit into the space delimited by the inner peripheral surface 34 . The cylindrical outer surface 56 of the pin receptacle 14 has a slightly larger diameter than the inner peripheral surface 34 of the valve body 4 . The pin receptacle 14 is thus firmly fixed in the valve body 4 , with axial positioning using the stop 50 of the valve body 4 and the annular raised area 52 of the pin receptacle 14 .

Fig. 5 shows a third embodiment of a gas flow monitor according to the invention 1, which is a combination of gas flow monitor and thermal safety device. It has a valve body 4 , which can be connected via threads 60 , 62 to pipe sections of a pipeline, not shown. In the valve body 4 is a two-part pin receptacle 14 ', 14 "are provided. The first part 14' is secured to the valve body 4 by means of a press fit. In the second part 14" of the pin 20 is guided axially displaceably. The two parts 14 ′, 14 ″ of the pin receptacle 14 are detachably connected to one another. The shut-off body 24 is fastened to the pin 20 by means of a clamp fit. The holding means 22 act - as described above - between the first stop 44 and the second stop 45 or between the shut-off body 24 and the valve body 4. the function of the gas flow monitor 1 shown in Fig. 5 corresponds to the function of the gas flow switch 1 shown in Fig. 1 and 2. However, 14 "may be an auxiliary function by the separation of the pin receptacle 14 in two parts 14 ' be realized.

The parts 14 ', 14 "of the pin receptacle 14 are connected to each other through a melting means 64. In Fig. 6, the parts 14', 14" of the pin receptacle 14 partially recognizable. The melting means 64 , which is designed as a eutectic alloy, is introduced between them and melts when a predetermined limit temperature is reached. The second part 14 "of the pin receptacle 14 'is axially movable. Between the two parts 14' in molten melting means 64 relative to the pin receptacle 14, 14 'of the pin receptacle 14 acts an additional actuating element 66 in the form of a further pressure spring. With melted melting means 64 , the actuating element 66 presses the part 14 "of the pin receptacle 14 together with the pin 20 , the holding means 22 and the shut-off body 24 in the direction of the valve seat 36 until the shut-off body 24 comes to rest there. As a result, the shut-off body 24 is released from its flow position moved to the sealing position.

The gas flow monitor 1 shown in FIG. 5 closes both at impermissibly high gas flow values and at impermissibly high temperatures. Protection against excessive gas flow rates and excessive temperatures can thus be used to implement two safety functions in gas-carrying systems in a single component.

Fig. 7 shows a fourth embodiment of a gas flow monitor 1 according to the invention with a valve body 4 , which can be connected via threads 60 , 62 to pipe pieces of a pipeline, not shown. In the valve body 4 is a two-part pin receptacle 14 ', 14 "are provided. The first part 14' is secured to the valve body 4 by means of a press fit. In the second part 14" of the pin 20 is guided axially displaceably. The two parts 14 ', 14 "of the pin receptacle 14 are detachably connected to one another. The shut-off body 24 is fastened to the pin 20 by means of a clamp fit. The holding means 22 act - as described above - between the first stop 44 and the second stop 45 or between the shut-off body 24 and the valve body 4. The function of the gas flow monitor 1 shown in FIG. 7 corresponds to the function of the gas flow monitor 1 shown in FIG .

The gas flow monitor shown in FIG. 7 is in the flow-through position, ie the shut-off body 24 is arranged in such a way that gas can flow through the gas flow monitor 1 . The gas can pass through an annular region formed between the valve seat 36 and the seal 26 of the shut-off body 24 . The gas can thus flow through the gas flow monitor 1 from one pipe section of the pipeline into the other pipe section.

If the gas flow exceeds a permissible value, the holding means 22 is compressed in such a way that the seal 26 of the shut-off body 24 comes into contact with the valve seat 36 and thus blocks the gas flow path (see FIG. 8).

If a predeterminable permissible limit temperature is exceeded, the gas flow monitor shown in FIG. 7 is likewise brought into a sealing position in accordance with FIG. 9. For this purpose, the parts 14 ', 14 are "of the pin receptacle 14 connected by a melting means 64. The melting means 64 are, for example, formed as an eutectic alloy, melting at reaching the temperature limit. The second part 14" of the pin receptacle 14 is in molten flux 64 axially movable relative to the pin receptacle 14 '. Between the two parts 14 ', 14 "of the pin receptacle 14 acts an additional actuating element 66 in the form of a further pressure spring. When molten flux 64, the actuator 66 pushes the part 14" of the pin receptacle 14 together with the pin 20, the holding means 22 and the shut-off 24 in the direction of the valve seat 36 until the seal 26 of the shut-off body 24 comes to rest there. As a result, the shut-off body 24 is moved from the flow position shown in FIG. 7 into the sealing position shown in FIG. 9.

Claims (28)

1. A method for producing a gas flow monitor ( 1 ) with an essentially cylindrical valve body ( 4 ), which has at least one through opening ( 38 ) for gas ( 32 ) flowing through the gas flow monitor ( 1 ), with one in the valve body ( 4 ) axially Slidably guided and essentially transverse to a gas flow ( 32 ) leading through the valve body ( 4 ) arranged shut-off body ( 24 ), which between a sealing position in which the shut-off body ( 24 ) rests on a valve seat ( 36 ) and the or each passage opening ( 38 ) is closed in a gas-tight manner, and a flow position in which the shut-off body ( 24 ) is lifted off the valve seat ( 36 ) and the or each through opening ( 38 ) is free to move, and with a first stop ( 44 ) assigned to the shut-off body ( 24 ) ), a second stop ( 45 ) assigned to the valve body ( 4 ) and between the two stops ( 44 , 45 ) This involves elastically deformable holding means ( 22 ) which exert a force opposing the gas flow ( 32 ) on the shut-off body ( 24 ), the distance of the two stops ( 44 , 45 ) from one another being set in the axial direction in the course of the production of the gas flow monitor ( 1 ) characterized in that to set the nominal flow the maximum distance between the two stops ( 44 , 45 ) to each other in the flow position and / or to set the closing flow the maximum distance between the two stops ( 44 , 45 ) to each other in the sealing position by means of a clamp fit is limited. - 2. Manufacturing method according to claim 1, characterized through the following process steps: - The shut-off body ( 24 ) is brought into the flow position or into the sealing position; - An adjustment force is determined which corresponds to the force which acts on the shut-off body ( 24 ) in the axial direction at the nominal flow or at the closing flow through the gas flow ( 32 ); - The first stop ( 44 ) is acted upon in the flow direction of the gas with the adjusting force; and - A maximum relative position between the first stop ( 44 ) and the shut-off body ( 24 ) is limited by means of a clamp fit. 3. Manufacturing process according to claim 1, characterized by the following process steps: - The shut-off body ( 24 ) is brought into the open position or in the sealing position; - An adjustment force is determined which corresponds to the force which acts on the shut-off body ( 24 ) in the axial direction at the nominal flow or at the closing flow through the gas flow ( 32 ); - The second stop ( 45 ) is acted against the flow direction of the gas with the adjusting force; and - A maximum relative position between the second stop ( 45 ) and the valve body ( 4 ) is limited by means of a clamp fit. 4. Manufacturing method according to one of claims 1 to 3, characterized in that the first stop ( 44 ) or the second stop ( 45 ) is acted upon by means of weights or by means of an adjusting element with the determined setting force. 5. Manufacturing method according to one of claims 1 to 4, characterized in that the adjusting force is determined as a function of the later installation position of the gas flow monitor ( 1 ). 6. The manufacturing method according to claim 1 or 2, characterized in that the first stop ( 44 ) in the relative position set between the first stop ( 44 ) and the shut-off body ( 24 ) is fastened to the shut-off body ( 24 ) by means of a clamp fit. 7. The manufacturing method according to claim 1 or 3, characterized in that the second stop ( 45 ) is fixed in the relative position between the second stop ( 45 ) and the valve body ( 4 ) on the valve body ( 4 ) by means of a clamp fit. 8. The manufacturing method according to claim 1 or 2, characterized in that the first stop ( 44 ) is formed on an axially extending pin ( 20 ) which is axially displaceably guided in the valve body ( 4 ) and which is acted upon by the first Stop ( 44 ) is displaced with the adjusting force relative to the shut-off body ( 24 ) in the flow position or sealing position, and the maximum relative position that is established between the first stop ( 44 ) and the shut-off body ( 24 ) is limited with the aid of an additional clamping element , wherein the clamping element is fastened by means of a clamp seat on a side of the pin ( 20 ) opposite the first stop ( 44 ) when viewed from the shut-off body ( 24 ). 9. The manufacturing method according to claim 1 or 3, characterized in that the second stop ( 45 ) is formed on an axially extending pin ( 20 ) on which the shut-off body ( 24 ) is guided axially displaceably and which is acted upon by the second Stop ( 45 ) is displaced with the adjusting force relative to the valve body ( 4 ), and the maximum relative position that is established between the second stop ( 45 ) and the valve body ( 4 ) is limited with the aid of an additional clamping element, the clamping element being clamped on one of the valve body ( 4 ) viewed from the second stop ( 45 ) opposite side of the pin ( 20 ) is attached. 10. Gas flow monitor ( 1 ) with an essentially cylindrical valve body ( 4 ), which has at least one through opening ( 38 ) for gas ( 32 ) flowing through the gas flow monitor ( 1 ), with an axially displaceably guided in the valve body ( 4 ) and in Shut-off body ( 24 ) which is arranged essentially transversely to a gas flow ( 32 ) leading through the valve body ( 4 ) and closes between a sealing position in which the shut-off body ( 24 ) rests on a valve seat ( 36 ) and seals the or each through opening ( 38 ) in a gas-tight manner , and a flow position, in which the shut-off body ( 24 ) is lifted off the valve seat ( 36 ) and the or each through opening ( 38 ) opens, is displaceable, and with a first stop ( 44 ) assigned to the shut-off body ( 24 ), one of which Valve body ( 4 ) assigned second stop ( 45 ) and between the two stops ( 44 , 45 ) arranged elastically deformable H old means ( 22 ) which exert a force opposing the gas flow ( 32 ) on the shut-off body ( 24 ), a distance between the two stops ( 44 , 45 ) from one another being adjustable in the axial direction, characterized in that a maximum distance between the two stops ( 44 , 45 ) is limited to each other by means of a clamp fit. 11. Gas flow monitor ( 1 ) according to claim 10, characterized in that the shut-off body ( 24 ) is fastened to the first stop ( 44 ) by means of a clamp seat. 12. Gas flow monitor ( 1 ) according to claim 10, characterized in that the valve body ( 4 ) is fastened to the second stop ( 45 ) by means of a clamp seat. 13. Gas flow monitor ( 1 ) according to one of claims 10 to 12, characterized in that guide means ( 14 , 16 , 18 , 20 ) for guiding the shut-off body ( 24 ) in the valve body ( 4 ) are provided, the guide means ( 14 , 16 , 18 , 20 ) are part of a valve insert which is fixed in the valve body ( 4 ) by means of a press fit. 14. Gas flow monitor ( 1 ) according to claim 13, characterized in that the valve body ( 4 ) has a stop region ( 50 ) up to which the valve insert is inserted into the valve body ( 4 ) and on which the valve insert rests. 15. Gas flow monitor ( 1 ) according to one of claims 10 to 14, characterized in that guide means ( 14 , 16 , 18 , 20 ) for guiding the shut-off body ( 24 ) in the valve body ( 4 ) are provided, the guide means ( 14 , 16 , 18 , 20 ) comprise a pin receptacle ( 14 ) in which the pin ( 20 ) attached to the shut-off body ( 24 ) is guided so as to be axially displaceable, the pin receptacle ( 14 ) viewed in the axial direction only on one side of the shut-off body ( 24 ) is arranged. 16. Gas flow monitor ( 1 ) according to claim 15, characterized in that the pin ( 20 ) in the pin receptacle ( 14 ) is guided at least two guide regions spaced apart in the axial direction. 17. Gas flow monitor ( 1 ) according to claim 15, characterized in that the pin ( 20 ) on the shut-off body ( 24 ) is fastened by means of a clamp seat. 18. Gas flow monitor ( 1 ) according to one of claims 10 to 14, characterized in that guide means ( 14 , 16 , 18 , 20 ) for guiding the shut-off body ( 24 ) in the valve body ( 4 ) are provided, the guide means ( 14 , 16 , 18 , 20 ) comprise a pin receptacle ( 14 ), in which the pin ( 20 ) is fastened, on which the shut-off body ( 24 ) is guided in an axially displaceable manner, the pin receptacle ( 14 ) viewed in the axial direction only on one side of the Shut-off body ( 24 ) is arranged. 19. Gas flow monitor ( 1 ) according to claim 18, characterized in that the pin ( 20 ) on the valve body ( 4 ) is fastened by means of a clamp seat. 20. Gas flow monitor ( 1 ) according to one of claims 15 to 19, characterized in that the pin receptacle ( 14 ), viewed in the axial direction, is arranged on a side of the shut-off body ( 24 ) opposite the valve seat ( 36 ). 21. Gas flow monitor ( 1 ) according to one of claims 10 to 20, characterized in that the holding means ( 22 ) are designed as a spring element, preferably as a spiral spring. 22. Gas flow monitor ( 1 ) according to claim 21, characterized in that the spring element is designed as a compression spring. 23. Gas flow monitor ( 1 ) with an essentially cylindrical valve body ( 4 ), which has at least one through opening ( 38 ) for gas ( 32 ) flowing through the gas flow monitor ( 1 ), with an axially displaceably guided in the valve body ( 4 ) and in Shut-off body ( 24 ) which is arranged essentially transversely to a gas flow ( 32 ) leading through the valve body ( 4 ) and closes between a sealing position in which the shut-off body ( 24 ) rests on a valve seat ( 36 ) and seals the or each through opening ( 38 ) in a gas-tight manner , and a flow position in which the shut-off body ( 24 ) is lifted off the valve seat ( 36 ) and the or each passage opening ( 38 ) is free to move, and with a first stop ( 44 ) associated with the shut-off body ( 24 ), one of which Valve body ( 4 ) assigned second stop ( 45 ) and between the two stops ( 44 , 45 ) arranged elastically deformable H old means ( 22 ) which exert a force directed against the gas flow ( 32 ) on the shut-off body ( 24 ), a distance between the two stops ( 44 , 45 ) from one another being adjustable in the axial direction, in particular according to one of claims 10 to 22, thereby characterized in that the holding means ( 22 ) act in a temperature-dependent manner, the force exerted by the holding means ( 22 ) on the shut-off body ( 24 ) and opposing the gas flow ( 32 ) dropping steeply when a predetermined limit temperature is exceeded. 24. Gas flow monitor ( 1 ) according to claim 23, characterized in that the temperature-dependent holding means are formed from a eutectic metal alloy. 25. Gas flow monitor ( 1 ) according to one of claims 13 to 24, characterized in that the valve insert comprises at least two components ( 14 ', 14 "), between which temperature-dependent lubricants ( 64 ) are introduced, the lubricants ( 64 ) below one Predeterminable limit temperature inhibit an axial displacement of the components ( 14 ', 14 ") relative to each other and above the limit temperature allow the displacement of the components ( 14 ', 14 ") relative to each other. 26. Gas flow monitor ( 1 ) according to claim 25, characterized in that the gas flow monitor ( 1 ) comprises an actuating element ( 66 ) which acts between two of the components ( 14 ', 14 ") and, in the case of molten melting means ( 64 ), a movement of the shut-off body ( 24 ) caused in the sealing position. 27. Gas flow monitor ( 1 ) according to claim 26, characterized in that the actuating element ( 66 ) is designed as a compression spring.