DE10351041B4 - Excess flow valve - Google Patents

Abstract

Gas flow monitor (10) to the automatic close a gas conduit (28) having a tubular housing (11) defining a valve seat (11a), a valve body (19), the verschliechtlich in a housing (11) held guide member (14) is mounted, and a spring (20), the valve body (19) against the gas flow direction (S) acted upon in an open position, wherein in the valve body (19) an overflow hole (26) is formed which a gas flow through the in the closed position allows the valve seat (11a) adjacent valve body (19) through, characterized in that the overflow bore (26) on the gas flow (S) facing side of the valve body (19) is associated with a shielding element (25) spaced from a Inflow opening (26a) the overflow hole (26) is arranged.

Description

The The invention relates to a gas flow monitor for automatic close a gas conduit with a tubular housing having a valve seat, a valve body, slidably mounted in a housing held on the guide part is, and a spring, the valve body against the flow direction acted upon in an open position, wherein in the valve body an overflow hole is formed, which is a gas flow by the in the closed position allows valve body seated on the valve seat therethrough.

One Such gas flow monitor finds particular for gas fittings and gas house entries use to a Gas line automatically shut off when in the gas line an excessively high gas flow, for example occurs as a result of a consumer-side high gas extraction, the may be due to a defect or a leak.

One from the brochure "Gas flow monitor SENTRY GS for underground pipelines "of the Mertik Maxitrol GmbH & Co. KG has known gas flow monitor a tubular Housing, the flows through the gas becomes. Inside the case is a ring-shaped Valve seat formed, which cooperates with a plate-shaped valve body. The valve body sits on a guide pin that in the axial direction of the housing, i.e. in the flow direction of the gas extends. At or near the input section and / or the output cross-section of the housing is a storage for the guide pin provided on the housing fastened and in particular clamped and in which a middle Axial bore is formed through which the guide pin extends. On this way is the valve body carrying guide pin Slidably mounted in the axial direction.

Of the valve body is by means of a guide pin attached coiled spring against the flow direction of the gas in his open position biased, in which he is at a considerable distance from the valve seat. In normal operation of the gas flow monitor can the gas the valve body flow around and pass through the gas flow monitor. Of the Flow area, the area of the valve body and the bias of the spring are coordinated so that the valve body when crossing a predetermined value of the gas dynamic pressure against the force the spring moved to its closed position is, in which it rests sealingly against the valve seat and thereby the Gas line closes.

After this the valve body with the valve seat has entered into sealing contact and thereby the gas line has closed, lies on the gas supply facing Side of the valve body, i.e. upstream of the gas flow, the gas pressure on, the the valve body clamped against the valve seat. If the problem that led to the closure of the gas flow monitor for example, a leak downstream of the gas flow monitor, is corrected, the valve body must counter the gas pressure be brought back into the open position. To this Purpose is known to produce a gas pressure surge downstream of the gas flow monitor and thereby the valve body to adjust. However, this procedure is complicated and time-consuming.

Around the generation of a gas pressure surge to return the valve body to avoid, it is known in the valve body, a so-called overflow through which the gas is also in the closed position of the valve body flow through can. The cross section of the overflow hole However, it is so small that a maximum of 30 liters of gas per hour can flow through. These Quantity is so low that it even in the case of a downstream Leakage brings no danger.

If the gas flow switch closed is and the problem that has led to closure of the gas flow monitor fixed, finds through the overflow hole between the upstream side of the valve body, on the gas pressure is present, and the downstream side of the valve body a gradual Pressure equalization instead of what causes that the valve body pressed into its open position as a result of the force of the spring, when the pressure on the two sides of the valve body is complete or at least approximately Completely is balanced. This way is an automatic reset of the valve body from the closed position possible in the open position.

Since the maximum permissible flow through the overflow is very small, and the diameter of the overflow is very small and is usually in the range of 0.05 to 0.1 mm, and in particular 0.08 mm. In the open position of the gas flow monitor, which forms the normal position, the gas flows around the valve body, so that practically no gas flow takes place through the overflow bore. This has in practice led to the problem that small particles of dirt entrained in the gas can settle in the overflow hole and clog it up during the relatively long time that the gas flow monitor is normally open. If the gas flow switch then closes as a result of a downstream problem, then Overflow no gas flow through it, so that even after the problem has been solved no pressure equalization takes place and no automatic return of the valve body takes place in the open position.

Of the Invention is based on the object, a gas flow monitor of to create said type, which reliably a self-provision of the valve body ensured in the open position.

These The object is achieved by a Gas flow monitor with the characterizing features of claim 1 solved.

there is provided that the overflow hole on the gas flow facing side of the valve body a shielding element is associated with the distance from an inflow opening of the overflow is arranged. The shielding reliably prevents that the gas in direct, axial flow into the overflow hole arrives. To the overflow hole to be able to enter the gas must flow around the shielding element. In the open Normal position of the gas flow monitor flows the gas past the valve body, wherein the shield simultaneously acts as a guide to to keep the gas away from the overflow hole. In this way it is ensured that in the gas flow eventually entrained dirt particles not in the overflow hole but either flow past the shielding and the valve body or bouncing on the shielding. It has been shown that by means of the shielding even after a long period of operation pollution the overflow hole reliable can be avoided.

In a preferred embodiment of the invention is provided that that Shielding a substantially perpendicular to the gas flow extending feed forms, through which the gas reaches the overflow hole. It is the design chosen that in the open normal position of the valve body at this passing Gas due to the Venturi effect in the supply channel causes a negative pressure, which leads to, that the feed channel and the overflow hole be kept clean because there are no dirt particles due to the negative pressure can settle. In an advantageous embodiment of the invention, it is provided that the vertical body sitting in a conventional manner on an axial guide pin and the guide pin the valve body penetrates and on the gas flow side facing with a End protruding from this and that the shielding on the protruding end of the guide pin is appropriate.

there the shielding element can be cap-shaped trained and on the protruding end of the guide pin be set up. If the shielding element made of plastic and in particular an elastic plastic, it may have a blind hole, with it under elastic expansion on the protruding end of the guide pin is postponed. In this way, the shielding is on the protruding end of the guide pin clamped.

alternative but it is also possible that the shielding element on the protruding end of the guide pin attached in a different way and in particular screwed on, glued or pressed on.

Preferably serves the shielding simultaneously to the gas in the open Normal position of the valve body to turn it around, i. the axially flowing gas to the edge of the valve body directional change of direction to give. For this purpose may be provided in a further development of the invention be that the shielding formed approximately rotationally symmetrical is, wherein only the radially extending feed channel the rotational symmetry disturbs. The deflection of the gas is achieved in that the shielding to the gas flow facing side tapered conically and in particular rounded on its side facing the gas flow side is, so it's the shape of a cone and especially one on the tip has rounded cone.

Around to ensure, that the overflow hole with the feed channel in fluidic Connection is and not accidentally through the shield is closed, the shield should be secured against rotation on the protruding end of the guide pin and in particular on the valve body be held.

Further Details and features of the invention will become apparent from the following description an embodiment with reference to the drawing. Show it:

1 a cross section through a gas flow monitor according to the invention, wherein the valve body is in the lower part of the drawing in its open position and in the upper part of the drawing in its closed position,

2 a partially sectioned, enlarged side view of the valve body and

3 the view III in 2 , where the Ab Part screen element is partially omitted.

According to 1 has a gas flow monitor 10 a substantially tubular housing 11 on, a circumferential, radially outwardly projecting collar 12 has. On the radial outer side is an annular groove 12a formed into a seal 13 is used in the form of an O-ring. The gas flow monitor 10 lies in the installed state on the inner wall of a gas line 28 and is opposite to this through the seal 13 sealed. The axial positioning of the gas flow monitor 10 in the gas line 28 is through at the gas line 28 internally formed stops 28a ensured.

The housing 11 of the gas flow monitor 10 has an inner axial passage 11b which according to 1 From left to right is traversed by gas, as indicated by the gas flow representing arrow S. Inside the case 11 is at a cross-sectional constriction of the passage 11b an annular valve seat 11a educated.

On the side facing away from the gas inlet is inside the housing 11 a section 11c provided enlarged diameter, on the inner wall a circumferential locking groove 24 is trained. A guide part, which is designed as a one-piece plastic part, comprises an annular body 15 , which on its radial outside a circumferential latch 15a having. The guide part 14 can with the ring body 15 axially into the section 11c enlarged diameter of the housing 11 be used, with the latch 15a with the locking groove 24 engages, causing the guide member 14 safely on the housing 11 is held.

The guide part 14 further comprises an axially in the housing 11 , in the 1 can be seen through the longitudinal center axis M, and thus parallel to the gas flow S extending, central bearing bush 17 , over several, over the circumference distributed webs 16 with the ring body 15 is integrally connected. Advantageously, three webs are provided in a mutual offset in the circumferential direction of 120 °.

A along the axial center axis M of the housing 11 extending guide pin 18 penetrates the bearing bush 17 at a central axial guide bore 17a under close fit. At the gas flow S remote from the end of the guide pin 18 ie at the downstream end of the guide pin 18 , is a stop body 22 arranged the movement of the guide pin 18 against the gas flow S, ie according to 1 to the left, limited. At the gas flow S facing the end of the guide pin 18 , ie at the upstream end of the guide pin 18 is at this a plate-shaped valve body 19 attached, a circumferential seal 23 carries in a circumferential radial groove 19a of the valve body 19 sits (see 2 ). In the lower half of the illustration in 1 is the valve body 19 in its open position, by the abutment of the stopper body 22 on the guide bush 17 is defined. In the upper half of the illustration of the 1 is the valve body 19 in his ner closed position in which the ring seal 23 at the valve seat 11a is applied.

At the valve body 19 facing end of the bearing bush 17 is in this one chamber 17b formed in the direction of the valve body 19 opens. In the chamber 17b is a coiled spring 20 inserted, with one end at the bottom of the chamber 17b supports and with its other end on an axial projection 19b of the valve body 19 sitting. The spring is supported 20 with her the valve body 19 opposite end at the bottom of the chamber 17b with the interposition of a spacer 21 from. Depending on the number and thickness of corresponding spacers 21 can be set a spring preload, which is the spring 20 in the open position on the valve body 19 exerts, causing the valve body 19 against the gas flow S is biased in its open position.

As 1 shows, is the spring 20 in the open position of the valve body 19 about half their axial length within the chamber 17b while the other, exposed half of the gas flow largely through the valve body 19 is shielded. In the closed position of the valve body 19 there is the spring 20 almost completely within the chamber 17b and is thus largely protected from interference and contamination.

Because the guide pin 18 only in the guide hole 17a slidably guided in the downstream portion of the bearing bush 17 is formed, it is ensured that the valve body 19 over the guide pin 18 cantilevered in the direction of the gas flow S is held.

In particular 2 is in the valve body 19 an axially extending overflow bore 26 ausgebil det whose dimensions are so small that a maximum of 30 liters of gas per hour can pass.

The guide pin 18 penetrates the valve body 19 at a hole 19c complete and stands with its the gas flow S facing the end 18a from the valve body 19 out. On the forth standing end 18a of the guide pin 18 is a cap-like shielding element 25 placed. The shielding element 25 consists of plastic and has an axial blind hole 25a on, with it under close fit on the free end 18a of the guide pin 18 sitting. The shielding element 25 has a substantially rotationally symmetrical shape and tapers on its side facing the gas flow S and is rounded at its, the gas flow S facing tip so that it has a total approximately the shape of a rounded circular cone.

The dimensions of the valve body 19 seated base of the shielding 25 are so big that the overflow hole 26 is in the region of the base, wherein in the shielding 25 a substantially radially extending feed channel 27 is provided, through the gas to the overflow 26 can get. Another gas supply to the overflow hole 26 is not scheduled.

As 3 are shown are over the outer peripheral edge of the cap-like shielding 25 several recesses 25b distributed, with corresponding protrusions 19d of the valve body 19 engage, whereby the shielding 25 non-rotating on the valve body 19 is held. In this way prevents the shielding 25 relative to the valve body 19 twisted, which would involve the risk that the shielding 25 the overflow hole 26 covered. The rotation lock ensures that the overflow hole 26 always with the supply channel 27 and thus with the interior of the gas line 28 is in fluidic connection.

In the normal state of the gas flow monitor 10 is the valve body 19 in its open position. The inflowing gas strikes the cone-shaped shielding element 25 , which makes it laterally outward to the edge of the valve body 19 is deflected and flows around it. In this case, a negative pressure is generated in the supply channel due to the Venturi effect as a result of the gas flowing past, which prevents dirt particles in the feed channel 27 or the overflow hole 28 can settle. The flow area of the housing 11 , the size of the valve body 19 and the bias of the spring 20 are coordinated so that the valve body 19 from its open position against the force of the spring 20 is moved to its closed position and the gas flow monitor 10 closes when the flow of gas to the valve body 19 applied back pressure exceeds a predetermined value. In the closed position of the valve body 19 stands on the according 1 left side of the gas pressure, through which the valve body 19 against the valve seat 11a is tense. In this position, a small gas flow through the feed channel 27 and the overflow hole 28 on the downstream side of the valve body 19 instead of. If in the downstream of the gas flow monitor 10 lying pipeline network no leakage or no other gas sampling takes place, builds downstream of the valve body 19 as a result of the overflow hole 26 passing through a gas pressure and there is a pressure equalization between the two sides of the valve body 19 instead of. At the latest at complete pressure equalization of the valve body 19 due to the action of the spring 20 automatically returned to its open position, whereupon the gas back to the valve body 19 flows around the outside. If in the meantime in the feed channel 27 or the overflow hole 26 Dirt particles should have accumulated, they are sucked by the self-adjusting vacuum.

Claims (10)

Gas flow monitor ( 10 ) for automatically closing a gas line ( 28 ), with a tubular housing ( 11 ), which has a valve seat ( 11a ), a valve body ( 19 ), which is slidable in one of the housing ( 11 ) held leadership part ( 14 ) and a spring ( 20 ), which the valve body ( 19 ) against the gas flow direction (S) in an open position, wherein in the valve body ( 19 ) an overflow hole ( 26 ) is formed, which a gas flow through the in the closed position on the valve seat ( 11a ) adjoining valve body ( 19 ), characterized in that the overflow bore ( 26 ) on the gas flow (S) facing side of the valve body ( 19 ) a shielding element ( 25 ), which is at a distance from an inlet opening ( 26a ) of the overflow bore ( 26 ) is arranged. Gas flow monitor according to claim 1, characterized in that the shielding element ( 25 ) has a feed channel extending substantially perpendicular to the gas flow (S) ( 27 ), through which the gas to the overflow ( 26 ). Gas flow monitor according to claim 1 or 2, characterized in that the valve body ( 19 ) a guide pin ( 18 ) carrying the valve body ( 19 penetrates and protrudes on the side facing the gas flow (S) from this and that the shielding ( 25 ) at the protruding end ( 18a ) of the guide pin ( 18 ) is attached. Gas flow monitor according to claim 3, characterized in that the shielding element ( 25 ) cap-shaped and on the protruding end ( 18a ) of the guide pin ( 18 ) is set. Gas flow monitor according to one of claims 1 to 4, characterized in that the shielding element ( 25 ) is formed substantially rotationally symmetrical. Gas flow monitor according to one of claims 1 to 5, characterized in that the shielding element ( 25 ) on the protruding end ( 18a ) of the guide pin ( 18 ) is compressed. Gas flow monitor according to one of claims 1 to 6, characterized in that the shielding element ( 25 ) consists of plastic. Gas flow monitor according to one of claims 1 to 7, characterized in that the shielding element ( 25 ) tapers conically towards the side facing the gas flow (S). Gas flow monitor according to one of claims 1 to 8, characterized in that the shielding element ( 25 ) is rounded on its side facing the gas flow (S) side. Gas flow monitor according to one of claims 1 to 9, characterized in that the shielding element ( 25 ) rotatably on the valve body ( 19 ) is held.