RU2079906C1 - Device for measuring neutron fluxes from a nuclear reactor - Google Patents

Abstract

FIELD: nuclear power engineering; water-water power reactor installations. SUBSTANCE: device has a channel having three parts and inserted through a penetration in a concrete reactor vault. One end part of the channel can move along its axis in the penetration. Middle part is positioned within the zone of reactor vessel tubes and has joints allowing the middle part to be removed. The other end part is fixed in the vault. EFFECT: improved design. 8 cl, 1 dwg

Description

 The invention relates to devices for arranging and moving an ionization chamber in them and can be used in structures for monitoring nuclear reactors at nuclear power plants.

 A device for moving the ionization chamber [1] containing a channel housing located in the biological protection of the reactor, a counterweight and a drive mechanism. The channel body is made in the form of two loops, one of which is attached to the drive, and the second is a counterweight.

 The disadvantage of this device is that for its maintenance (installation of an ionization chamber in it or extraction when it fails), an additional room is required, which is located below the shaft of a nuclear reactor, which increases the volume of construction and the cost of a nuclear power plant.

 The closest technical solution is a device for measuring the neutron flux [2] located in a concrete mine and consisting of an external sealed pipe, an inner pipe, a bottom and fittings for supplying and removing ventilation air, an ionization chamber is placed inside the inner pipe. The outer pipe and the inner pipe in cross section form an annular channel. The device is located in the biological protection of a nuclear reactor. At the bottom of the inner pipe there is an opening for introducing cooling air.

 The disadvantage of this design is that the channel consists of two sealed pipes, and a violation of the density of one of them leads to depressurization and the second, so the channel is not very reliable. The presence of two pipes throughout the channel leads to a large metal structure. In addition, passing through the zone of the nozzles of the reactor vessel, the channels create oppression when monitoring the reactor vessel and pipelines.

 The technical result of the invention is: improving safety, increasing the reliability of ionization chambers, by reducing the surface that meets the tightness conditions, simplifying the design, reducing metal consumption and improving conditions for maintenance personnel during the monitoring and repair of the reactor vessel and pipelines in the area of the reactor pipes.

 The technical result is achieved by the fact that the channel body is made of three parts, one of the end parts being stationary mounted in the shaft, the middle part located in the area of the reactor nozzles is removable, the second end part is located in the shaft with a gap and can be moved in the direction of its longitudinal axis, and the connectors between the middle part and the end parts are equipped with sealing elements in the form of surfaces or inserts and tightening elements, providing a tight connection of the channel parts.

 In the analysis of the prior art, no solutions were found having features similar to the invention, i.e. it satisfies the criterion of "significant differences".

 The drawing shows a General view of the device.

 The essence of the invention lies in the fact that a channel is installed in the concrete shaft 1, consisting of a lower part 3, an average 4 and an upper 5. In this case, the lower part of the channel is installed in the shaft with a gap 6 with the possibility of movement along its axis. The lower part is provided with a bottom 16 and a fitting 7 for supplying ventilation air and, if necessary, a supply pipe 8, which can be located inside or outside the channel, and providing air supply to the blind end of the channel. The middle part of the channel 4, which, depending on the version, consists of straight sections, bent sections or a combination of straight and bent sections, is located in the area of the nozzles of the reactor vessel 2, the main circulation pipelines 9 and radiation protection 10. The channel in the middle part is equipped with connectors 11 and 12 The upper part of the channel is installed stationary in the concrete of the mine and is equipped with a fitting 13 and a device for outputting the cable 14 from the ionization chamber 15.

 The connector is made in the form of flange joints on studs between which gaskets are located. The connectors can also be filled without gaskets in the form of a coupling nut and ball-shaped sealing surfaces in a cone, or some other type of connector can be used.

 It is also possible to implement the device in such a way that the lower part of the channel 3 is installed in the shaft 1 stationary, and the upper part of the channel 5 is installed in the shaft with a gap and can be moved along its axis. The rest of the design remains unchanged.

 The device operates as follows: during installation, the lower part of the channel is installed in the penetration, fixed along the axis of the penetration and in height, so that after removing the clips, it is possible to move the lower part of the channel up and down. The middle part and the upper are mounted on the lower part. During the construction of the upper part of the shaft, the upper part of the channel is fixed in concrete. The latches on the bottom of the channel are removed. An ionization chamber is installed in the channels.

 When repairing and inspecting the reactor, the middle part of the channel is removed to prevent crowding in the area of pipes and pipelines and to provide access to pipelines and the reactor while freeing them from insulation and radiation protection.

 In this case, the lower connector is previously disconnected, the lower part of the channel is lowered, the upper connector is disconnected and the middle part of the channel is removed. Assemble in the reverse order.

 In the case when the upper end part of the channel 5 is installed in the shaft with a gap, the device operates as follows: when mounted in the shaft, the lower part of the channel 3 is stationary. The middle part is installed on the lower part, and then the upper part of the channel 5 is mounted with the possibility of movement along the axis.

 To remove the middle part of the channel, proceed as follows: disconnect the upper connector, raise the upper part of the channel, fix it in an elevated state, disconnect the lower connector and remove the middle part of the channel. Assemble in the reverse order.

Claims (8)

 1. A device for measuring the neutron flux of a reactor located in a concrete shaft, comprising a channel body, consisting of a pipe, a bottom, vent and air inlet fittings, characterized in that the channel body is made of three parts, one of the end parts being stationary mounted in shaft, the middle part located in the reactor service area is removable, the second end part is located in the shaft with a gap and can be moved in the direction of its longitudinal axis, and the connectors between the middle part and the end parts are equipped with sealing elements in the form of surfaces or inserts and tightening elements, providing a tight connection of the channel parts.  2. The device according to claim 1, characterized in that any of the two end parts of the channel is stationary mounted in a concrete shaft.  3. The device according to claims 1 and 2, characterized in that the middle part of the channel consists of straight sections.  4. The device according to claims 1 and 2, characterized in that the middle part of the channel consists of bent sections.  5. The device according to claims 1 and 2, characterized in that the middle part of the channel consists of straight and bent sections.  6. The device according to claims 1 and 2 and / or 3, characterized in that the end parts of the channel are located on the same axis.  7. The device according to claims 1 and 2 and / or 4 and / or 5, characterized in that the end parts of the channel are parallel to each other.  8. The device according to claims 1 and 2 and / or 4 and / or 5, characterized in that the end parts of the channel are located at an angle to each other.