RU2645833C1 - Protective plug of spent nuclear fuel storage hub and temperature sensor - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: group of inventions refers to the treatment of spent nuclear fuel (SNF). The protective plug of the storage hub with SNF includes a body formed by upper and lower discs and a shell filled with concrete. In the cork body, there is a stepwise penetration adjacent to the shell by its lower part, equipped with a threaded choke with a cap nut. In the stepwise penetration, a stepwise protective rod is disposed therefrom, between the stages of which a sealing ring is installed. There is also a temperature sensor. The temperature sensor contains thermoelectric converters with a ceramic insulation of the conductors enclosed in the tubes with the heat receivers installed in their lower part. The upper parts of the tubes are placed in the stepwise protective casing, which is configured to be installed in the penetration of the protective plug instead of the stepwise protective rod. The lower parts of the tubes are displaced relative to the upper ones by half the annular gap between the walls of the case and the body of the hub. The distance between the heat receivers in the free state of the tubes exceeds the width of the annular gap.

EFFECT: group of inventions allows to measure the temperature of the outer wall of the case and the hub in a dry storage.

5 cl, 4 dwg

Description

The invention relates to nuclear technology, in particular to the management of spent nuclear fuel, and more particularly to measuring the temperature of the walls of the spent nuclear fuel storage case (SNF) and the dry storage storage slot.

Storage slots installed between the upper and lower ceilings of the chamber consist of a head, pipe and bottom. The sockets are equipped with protective plugs installed in the sockets for welding after loading two canisters. The loading of the pencil cases and the installation of the cork are done by the reloading machine of the pencil cases. Two canisters are loaded into the storage slot, one on top of the other, while an annular gap is maintained between the canisters and the slot, the estimated value of which is 25 mm. In this case, the annular gap when viewed from above is half blocked by a protective plug. After welding the plug and socket joints, the cavity inside the socket is filled with nitrogen at a pressure of 0.06-0.07 MPa in order to control the tightness of the socket and the canisters placed in it during storage.

Known protective plug, made according to the drawing L.65.699.03.000 developed by the Federal State Unitary Enterprise "Head Institute" All-Russian Design and Research Institute of Integrated Energy Technology (VNIPIET) "St. Petersburg, containing a housing consisting of upper and lower disks and shell, filled with concrete. On the top of the plug are a bellows valve connecting the internal cavity of the nest with a sampling fitting, and a fungus designed to move the plug. To measure the temperature in the inner cavity of the nest, a tube bent along the arc is placed in the tube filled with concrete, the muffled end of which enters the nest. The temperature measurement of the nest is carried out by an industrial thermometer TK-5.04, a flexible probe of which containing a thermocouple is inserted into the tube.

The disadvantages of the known cork include the fact that in this case the temperature of the gaseous medium is measured, which does not give an idea of the actual temperatures of the walls of the pencil case and socket necessary for performing thermal calculations and determining the service life.

Known cork selected by the applicant as a prototype.

A device for measuring the temperature of the inner cylindrical surface (patent No. 2114403, IPC ⁶ G01K 1/14), containing a rod with a housing attached to it. A heat receiver is attached to the body, to which a thermocouple and elastic elements are connected to press the heat receiver to the inner surface of the controlled object (pipe).

The device is inserted inside the pipe, while the elastic elements press the heat receiver against it, providing thermal contact with the inner surface of the pipe.

The known device is accepted by the applicant as a prototype.

The task to which the invention is directed is to create the possibility of measuring the temperature of the outer wall of the canister, located in the storage slot of the dry storage, and the inner wall of the tube of the nest at the location of the active zone of the fuel bundles in the canister.

The technical result that can be obtained by using the proposed protective plug is the ability to install a temperature sensor in its penetration.

The specified technical result is achieved by the fact that in the proposed protective plug, in contrast to the known one, a step penetration is installed in the plug body adjacent to the shell with its lower part and welded to the upper and lower disks, equipped with a threaded fitting with a union nut, in the penetration with the possibility of extracting from it a stepped protective rod, between the steps of which a sealing ring is installed.

The installation of a stepped penetration in the protective plug adjacent to the shell with its lower part makes it possible to bring its axis horizontally as close as possible to the annular gap between the pencil case and the socket, which makes it possible to introduce the lower part of the temperature sensor into the annular gap.

The joining of stepped penetration in welding to the upper and lower disks allows sealing penetration along its outer surface and to ensure the maintenance of rarefaction in the socket during its operation.

Providing a penetration with a threaded fitting with a union nut, placing a stepped protective rod in the penetration and installing between the steps of the sealing ring allows the compression ring located between the steps of the penetration and the rod to be pressed with the help of a union nut resting on the step of the protective rod, and thereby sealing penetration along its inner surface and ensure the maintenance of rarefaction in the nest during its operation.

The technical result that can be obtained using the proposed temperature sensor is the ability to measure the temperature of the walls of the pencil case and socket in a dry storage.

The specified technical result is achieved by the fact that in the temperature sensor, including thermoelectric converters (thermocouples) with ceramic insulation of thermoelectrodes enclosed in tubes with heat sinks installed in the lower part of the tubes, and elastic elements for pressing the heat sinks to the surfaces of controlled objects, the upper parts of the tubes are placed in a step a protective casing made along the outer contour identical to a stepped protective rod.

The lower parts of the tubes are offset relative to the upper part of the tubes by half the annular gap between the walls of the pencil case and socket and are equipped with elastic elements. The distance between the heat sinks in the free position of the lower parts of the tubes exceeds the width of the annular gap.

In the particular case of execution, the upper parts of the tubes are placed in a stepped protective casing with their crossing, and the stepped protective casing is filled with shot.

In another particular case of execution, the heat sinks are located at the level of the active zone of the bundles of fuel rods of the upper case located in the pencil case.

In another particular case of execution, the elastic elements are made corresponding in shape to the lower part of the tubes and attached to them.

The placement of the upper parts of the tubes of the temperature sensor in a stepped protective casing, made in the outer contour identical to the stepped protective rod, makes it possible to replace the stepped protective rod with a temperature sensor while maintaining the tightness of the penetration along its inner surface, ensuring the preservation of vacuum in the socket during its operation.

The offset of the lower parts of the tubes relative to their upper parts by half the annular gap between the walls of the pencil case and the socket allows you to place the lower parts of the tubes parallel to the annular gap when installing the temperature sensor in the penetration and lowering the temperature sensor, introduce them into the annular gap in this position.

Exceeding the distance between the heat sinks with the width of the annular gap with the free position of the lower parts of the tubes allows, after introducing the lower parts of the tubes into the annular gap, by turning the temperature sensor to interact and compress the heat sinks to the walls of the pencil case and socket due to the elasticity of the tubes and to ensure thermal contact of one of the heat sinks with the outer wall of the pencil case, and the second - with the inner wall of the nest and, thus, get the opportunity to measure the temperature of the walls of the pencil case and nests in a dry storage.

The supply of the lower parts of the tubes with elastic elements allows to increase the amount of compression of the heat sinks to the walls and to provide a more reliable thermal contact between them.

Placing the upper parts of the tubes in a stepped protective casing with their crossing and filling the stepped protective casing with a fraction avoids direct "shots" of gamma radiation through the tubes.

The location of the heat sinks at the active zone level of the fuel rod bundles located in the upper pencil box allows you to measure the temperature of the wall of the pencil box in the most heated place.

The implementation of the elastic elements in the shape of the tubes and their attachment to the tubes allows you to introduce them into the penetration, and after its passage contributes to the adoption of the tubes in their original form.

The invention is illustrated by drawings, which depict:

in FIG. 1 - the proposed protective plug in the context;

in FIG. 2 - the proposed temperature sensor in the context;

in FIG. 3 - protective plug with a temperature sensor installed in it;

in FIG. 4 - position after rotation of the temperature sensor.

The proposed protective plug 1 (see Fig. 1) contains a housing 2 consisting of an upper 3 and a lower 4 discs, a ring 5 and a shell 6. The housing 2 is filled with concrete 7. In the housing 2 there is a stepped penetration 8 consisting of a glass 9 connected to the upper disk 3 for welding, and the tube 10 adjacent to the shell 6 and attached to the lower disk for welding 4. The glass 9 is equipped with a threaded fitting 11. An o-ring 12 and a stepped rod 13 are fixed in the stepped groove 8, which is fixed in the stepped groove 8 of the union nut 14.

The protective plug 1 is installed in the socket 15, including the head 16 and the pipe 17.

After installing the canisters 15 of the canisters 18, the nest 15 is sealed by welding the upper edges of the plug 1 and the head 16. When the canisters 18 are installed in the receptacle 15, an annular gap 19 remains between the walls of the canisters 18 and the pipe 17.

The proposed temperature sensor 20 (see Fig. 2) contains a stepped protective casing 21, made with the possibility of its installation in a stepped penetration 8 instead of a stepped rod 13. The casing 21 consists of a metal cylinder 22 and a pipe 23 connected to it with a bottom 24. B the housing 22 has the upper parts 25 of the tubes 26 passing through the holes in the cylinder 22 and the bottom 24 and protruding from the housing 21 with its lower part 27 to a height sufficient for their ends to reach the core level of the bundles 18 of fuel elements placed in the canister after installation and the housing 21 in tunneling 8. The tubes 26 are attached to the bottom 24 by welding. The upper parts 25 of the tubes 26 are installed in the tube 23 in the intersecting position, which allows to avoid direct "shots" of gamma radiation when filling the tube 23 with shot 28. At the ends of the lower part 27 of the tubes 26 are sealed, for example, for interference fit, heat sinks 29 made of a material with a high coefficient of thermal conductivity. The heat sinks 29 are made flats 30, increasing the area of thermal contact between the heat sinks and the walls of the pencil case and nests. In the tubes 26 thermoelectric converters (thermocouples) 31 are installed, for example TP-0188 / 2-1, with thermoelectrodes 32 enclosed in ceramic beads 33. Thermoelectric converters (thermocouples) 31 are connected to heat receivers 29. Connectors 34 are installed in the upper part of cylinder 22 to which thermoelectrodes 32 are connected.

The lower parts 27 of the tubes 25 are bent so that when the temperature sensor 20 is inserted into the penetration 8 (see Figs. 3 and 4), they are placed in the annular gap 19, and during the subsequent rotation of the temperature sensor 20 they provide thermal contact of one heat receiver 29 with the wall of the canister 18, and the second - with the pipe 17 of the socket 15. To the lower parts 27 of the tubes 26 are attached elastic elements 35.

The proposed protective plug 1 and the temperature sensor 20 are used as follows.

After the reloading machine installs the canisters 18 and the protective plug 1 in the slot 15 from the stepped penetration 8, a stepped protective rod 13 is removed and a temperature sensor 20 is installed instead of it (see Fig. 3). When the temperature sensor 20 is installed, it is positioned relative to the penetration 8 so that the lower parts 27 tubes 26 were located parallel to the annular gap 19, and for the possibility of their introduction into the pipe 10 were manually pressed against each other. After passing the penetration 8, the lower parts 27 due to the elasticity of the tubes 25 and the attachment of elastic elements 35 to them, restore their original position. After lowering the temperature sensor 20 into the penetration 8, the latter is rotated around the axis (see Fig. 4) until the flats 30 of one of the heat sinks 29 get into thermal contact with the wall of the canister 18 and the second with the pipe 17 of socket 15. The angle of rotation of the temperature sensor 20 is determined experimentally during bench tests of the temperature sensor 20. Next, the temperature sensor 20 is sealed in the penetration 8 by squeezing the sealing ring 12 with the union nut 14. Then, regular procedures are carried out to seal the socket 15, replace the air in it with nitrogen with yes leniem 0,06-0,07 MPa. The temperature of the walls is measured through the connectors 34 by connecting to a portable or stationary measuring device.

Claims (5)

1. The protective plug of the spent nuclear fuel storage case, including a housing formed by upper and lower disks and a shell filled with concrete, characterized in that a step penetration is installed in the plug housing adjacent to the shell with its lower part and welded to the upper and to the lower disks, equipped with a threaded fitting with a union nut, a stepped protective rod is placed in the stepped penetration with the possibility of extraction from it, between the steps of which a sealing ring is installed about. 2. Thermal sensor, including thermoelectric converters (thermocouples) with ceramic insulation of thermoelectrodes, enclosed in tubes with heat sinks installed in the lower part of the tubes, and elastic elements, characterized in that the upper parts of the tubes are placed in a stepped protective casing, made on the outer contour identical to the stepped to the protective rod, the lower parts of the tubes are offset relative to their upper parts by half the annular gap between the walls of the pencil case and socket and are equipped with elastic elements, when the distance between the heat receiving it in the free state the tubes exceeds the width of the annular gap. 3. The temperature sensor according to claim 2, characterized in that the upper parts of the tubes are placed in a stepped protective casing with their crossing, and the stepped protective casing is filled with shot. 4. The temperature sensor according to claim 2, characterized in that the heat sinks are located at the level of the active zone of the bundles of fuel rods of the upper case located in the pencil case. 5. The temperature sensor according to claim 2, characterized in that the elastic elements are made similar in shape to the tubes and are attached to them.

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