DE2739377A1 - Automatic cut=off valve for piping carrying radioactive gas - has pendulum flap responding to excess gas velocity, for use in nuclear reactor circuits - Google Patents

Abstract

The cut-off valve includes a freely suspended pendulum flap which leaves the inlet and outlet open within a hollow cylinder, without causing an obstruction. An excessive gas glow rate, caused by a fractured output pipe, causes the flap to swing against the outlet seat, where it is held by the excess (> atmospheric) pressure. The valve has a simple design; functions reliably after long operational periods and is easily returned to its initial position after a response.

Description

7 6

HIGH TEMPERATURE REAKTORBAU GmbH Hansaring 53 5000 Cologne

Automatic shut-off device acting in one direction of flow

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- -er- 7 6 10

The invention relates to an automatic shut-off device for a radioactive gas which acts in one direction of flow Leading pipeline system that has a sheathed extraction line and a non-sheathed differential pressure line connected to it includes.

State of the art are pipeline systems with protective devices, which come into operation if a pipeline breaks or leaks. Such devices are for example used in hydraulic systems to prevent a hydraulically moving device from suddenly falling when the desired flow rate of the pumped medium is exceeded as a result of a broken pipe.

For example, in the laid-open specification 25 07 313, a pipe rupture protection device described, which has a valve body acted upon in both flow directions by the medium flow, which is from an adjustable device is held in its starting position. When a specified flow velocity is exceeded of the medium, the valve body is released and closes the pipeline. The adjustable facility consists of a ball that engages in a groove on the circumference of the valve body, and a spring, the preload with a Adjusting screw can be changed continuously. With this pipe burst protection there is a risk that after a long period of operation safe functioning is no longer guaranteed due to decreasing spring force.

The laid-open specification 25 47 912 discloses a valve device known for the protection of pipe systems against unintentional pressure drops that automatically reduce the flow through a particularly exposed pipe section, e.g. a flexible one

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Hose that comes to a standstill when the pressure is in undesirable Way changes. The device consists of one located in the inlet opening of the controlled section Shut-off valve and a flow sensor of the type a Venturi constriction, which is located at the outlet opening of the relevant Line section is attached. The shut-off valve and flow sensor are equipped with a pressure comparison device in connection, which compares the pressure drop in these two components and actuates the shut-off valve when the Ratio of the two pressure drop values falls below a specified value. This protective device is very expensive.

Pipe burst protection devices are also used in the primary circuits of nuclear reactors. In such circuits, care must be taken that only small amounts of the radioactive primary medium escape from the pipeline system in the event of pipe ruptures or leaks. In the published patent application 16 00 823 such a pipe rupture for a liquid metal in the temperature range between 200 ° and 1000 ⁰ C is described, which has a spherical or ellipsoidal blocking body made of metallic material. This is held in its open position by gravity on a ring-like support. Above the blocking body, the pipeline is designed like a cone. When a predetermined flow rate of the liquid metal is exceeded, the blocking body is lifted out of its holder and pressed into the conical line part, where it becomes stuck. Appropriate dimensioning of the blocking body diameter and the cone inclination ensures that the blocking body "seizes up" in its closed position, an intermetallic diffusion layer being formed between the blocking body and the conductive housing. A permanent closure of the blocked part of the line is established here. The well-known pipe burst protection is

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therefore not suitable for all purposes, apart from the fact that they are only used in vertical pipelines can be, since gravity is used to hold the locking body.

Proceeding from this prior art, the invention is based on the object for a pipeline system of the above type described to indicate an automatically operating shut-off device, in which the disadvantages of the known pipe burst protection can be avoided, i.e. which is simply structured, still works safely even after prolonged operation and afterwards can be easily returned to its original position after actuation.

According to the invention this object is achieved in that the shut-off device from a hollow cylinder with connection parts for the extraction line provided on its two end faces and the differential pressure line as well as one that is freely suspended in the hollow cylinder and one that is transverse to the longitudinal axis of the pipeline system extending axis swiveling pendulum flap exists, which in its normal position the cross-section of the pipeline system does not constrict and when a predetermined flow rate of the gas is exceeded by the dynamic pressure is pivoted in the direction of flow and thereby tightly closes the connection part for the differential pressure line.

In the steady state and with a low gas flow through the shut-off device, which is caused by the pressure fluctuations Can adjust the compressibility of the gas column located in the differential pressure line, the shut-off device remains open and releases a large cross-section. It is thus an unadulterated transmission of a measurement signal to the differential pressure line connected measuring device, e.g. a measuring

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converter, guaranteed. As soon as a pipe burst or a leak in the uncovered differential pressure line the gas flow through the shut-off device exceeds the specified level, the free-hanging pendulum flap will open pressed the back pressure on the connection part of the differential pressure line, whereby the gas flow from the extraction line into the Differential pressure line is interrupted. This prevents large amounts of the radioactive gas from escaping from the uncoated Differential pressure line are released. As a result of the differential pressure on both sides of the The pendulum flap remains closed.

The shut-off device according to the invention works completely reliably, because it cannot become clogged by graphite dust or the like, and there is also no danger the cold welding of the pendulum flap with the connection part of the differential pressure line or extraction line. A narrowing of the cross-section in the pipeline system in the area of the shut-off device is not available.

In an advantageous embodiment of the shut-off device according to the invention the two connection parts for the extraction line and the differential pressure line are designed as flanges, which are used as end faces in the jacket of the hollow cylinder and have passages for the gas, and the connecting part for the differential pressure line has a sealing seat inclined to the cross section of the pipeline system for the Pendulum flap open. The inclination of the sealing seat is adapted to the position of the pendulum flap when the shut-off device is closed. This embodiment allows the entire differential pressure and extraction line for the purpose of cleaning from the back to blow through the shut-off device.

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In order to be able to hang up the pendulum flap, a console is expediently provided in the upper part of the hollow cylinder, which is attached to the flange-like connection part for the differential pressure line or the extraction line. The pendulum flap can with the console can either be connected like a hinge, or it can be suspended from the console by means of a spiral spring.

The responsiveness of the shut-off device can be advantageous can be varied by changing the weight of the pendulum flap. With one suspended by means of a spiral spring The pendulum flap also has the option of influencing the sensitivity by choosing the thickness of the spiral spring to take the establishment. Thus, the shut-off device according to the invention be adapted to the prevailing flow conditions in any pipeline system, and it therefore there are many possible uses for them.

In the drawing are two embodiments of the invention Shut-off device shown schematically. The figures show in detail:

Fig. 1 is a longitudinal section through a first embodiment with a hinge-like suspension Pendulum flap,

Fig. 2 is a section along the line A-A of Fig. 1,

Fig. 3 shows a longitudinal section through a second embodiment with suspended on a spiral spring Pendulum flap,

Fig. 4 is a section along the line B-B of Fig. 3,

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5 shows the installation of the shut-off device in a

pipeline system charged with primary gas in a nuclear reactor facility.

Fig. 1 leaves a portion of a surrounded by a jacket 2 Detect extraction line 1, which is exposed to a radioactively contaminated gas, e.g. helium. She instructs flange-like connector 3, which with passages 4 for the gas is provided. The gas flows through the extraction line 1 in the direction indicated by the arrows.

The extraction line 1 is followed by a non-sheathed differential pressure line 5, which is also a flange-like one Has connector 6. This is provided with a passage for the gas.

The two connecting parts 3 and ß form the end faces of a hollow cylinder 8, in whose jacket they are welded. in the In the upper part of the hollow cylinder 8 there is a bracket 9 which is attached to the connecting part 6. At this console a pendulum flap 10 is suspended. As can be seen from Figure 2, the pendulum flap 10 is hinged to the console 9 and can pivot movements by a cotter pin run embodied axis 12.

The connection part 6 has a sealing seat 13, which corresponds to the cross section of the extraction line 1 and the differential pressure line 5 existing pipeline system with the axis 15 is inclined by approx. 15 °. This inclination is determined so that the Gas passage 7 is closed by the pivoted pendulum flap 10.

Hollow cylinder 8, pendulum flap 10 and the two connecting parts

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6 and 6 together form the shut-off device according to the invention 14, which has the task of preventing the outflow in the event of a pipe burst or a leak in the uncoated differential pressure line 5 to prevent larger amounts of the radioactively contaminated gas from the pipeline system. The shut-off device 1-1 speaks only when a specified flow velocity is exceeded of the gas. In such a case, the freely hanging pendulum flap 10 is caused by the back pressure of the flow pressed onto the sealing seat 13. Due to the resulting differential pressure, the pendulum flap 10 remains in this position, and the differential pressure line 5 is thus shut off (pendulum flap shown in dashed lines).

The responsiveness of the shut-off device 14 can can be varied within limits by changing the weight of the pendulum flap 10.

FIGS. 3 and 4 show a shut-off device 16 which is essentially constructed like the device just described. The same components are therefore denoted by the same reference numerals as in FIGS. 1 and 2.

The shut-off device 16 again consists of the hollow cylinder 8, the connecting part 3 and the connecting part 6 and a pendulum flap 17, which, however, is not designed like a hinge in its upper part. To connect the pendulum flap 17 with a bracket 18 attached to the connecting part 6 is provided here with a spiral spring 19, with the aid of which the pendulum flap 17 can be pivoted about an axis 20 running transversely to the longitudinal axis 15 of the pipeline system.

In the event of a pressure drop in the differential pressure line 5, the pendulum flap becomes 17 printed on the sealing seat 13 of the connecting part 6. By

... 10 /

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Changing the thickness of the spiral spring 19 can reduce the responsiveness the shut-off device 16 can be varied.

In Fig. 5 is an application example of the invention Shut-off device 14 or 16 shown. It is built into a pipeline system that consists of a helium-loaded Sampling line 1 and a non-jacketed differential pressure line 5 consists. The extraction line provided with a jacket 2 leads out of an armored tube 21, which is installed in a nuclear reactor pressure vessel 22-made of prestressed concrete and with a cover 23 is locked.

The differential pressure line 5 is connected to a transducer 24, in front of which a shut-off valve 25 is connected. A branch line 26 of the differential pressure line 5 leads to a blow-through valve 27. With the help of this valve it is possible to clean the entire differential pressure line 5 and extraction line 1 blown through from backwards, for which purpose the shut-off valve 25 is closed.

In the extraction line 1, two further end fittings 28 and 29 are provided, one of which is directly located in front of the shut-off device 14 or 16.

As can be seen from FIGS. 1 to 4, the inventive Shut-off device in its open position exposes a large cross-section, so that the transmission of a measurement signal through the extraction line 1 and differential pressure line 5 to the transducer 24 is not falsified.

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Claims (7)

7 3 10 Claims / LI ,1. Automatic shut-off device, acting in one direction of flow, for a pipeline system carrying radioactive gas, which comprises a jacketed extraction line and a non-jacketed differential pressure line connected to this, characterized in that the shut-off device (14; 16) consists of a hollow cylinder (3) with on its two end faces provided connection parts (3,6) for the Entnalimeleitung (1) and the differential pressure line (5) as well as from a pendulum flap freely suspended in the hollow cylinder (8) and pivotable about an axis (12; 20) running transversely to the longitudinal axis (15) of the pipeline system (10, 17), which in its normal position does not restrict the cross-section of the pipeline system and is swiveled in the direction of flow by the dynamic pressure when a predetermined flow rate of the gas is exceeded and thereby tightly closes the connection part (6) for the differential pressure line (5). 2. Automatic shut-off device according to claim 1, characterized in that the two connecting parts (3, 6) for the extraction line (1) and the differential pressure line (5) are designed as flanges which are used as end faces in the jacket of the hollow cylinder (8) and passages (4,7) for the gas, and that the connection part (6) for the differential pressure line (5) has a sealing seat (13) for the pendulum flap (10; 17) inclined to the cross section of the pipeline system, the inclination of the Sealing seat (13) is adapted to the position of the pendulum flap (10; 17) when the shut-off device (14; 16) is closed. 90981 1/0222 3. Automatic shut-off device according to claim 1 or 2, characterized in that the pendulum flap (10) is suspended on a console (9), wherein it is connected to it in a hinge-like manner. 4. Automatic shut-off device according to claim 1 or 2, characterized in that the pendulum flap (17) is suspended by means of a spiral spring (19) on a bracket (18). 5. Automatic shut-off device according to claim 1, 2, 3 or 4, characterized in that the responsiveness of the shut-off device (14) is varied by changing the weight of the pendulum flap (10). 6. Automatic shut-off device according to claim 4, characterized in that the responsiveness of the shut-off device (16) is varied by changing the thickness of the spiral spring (19). 90981 1/0222