JP2012032250A - Sodium condensing removal device for fast breeder reactor cover gas system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the sodium collection efficiency of a sodium condensing removal device.SOLUTION: The sodium condensing removal device includes: a vessel containing a filler for removing sodium; an inlet pipe which is attached to the vessel above the filler and supplies a gas containing sodium; an outlet pipe which is attached to the vessel below the filler and discharges a gas from which the sodium has been removed; and a heater which heats the inlet pipe. The device provides an improved sodium collection efficiency.

Description

  The present invention relates to a fast breeder reactor cover gas system sodium condensation type removal apparatus.

  FIG. 1 and FIG. 2 of Patent Document 1 relate to a fast breeder reactor cover gas system sodium removal method and disclose the structure of a sodium condensation type removal apparatus. In this sodium condensation type removal apparatus, argon gas preheated at about 500 ° C. is introduced from the lower part of the apparatus, rises inside the apparatus, and flows out from the upper part of the apparatus. Further, the filler inside the apparatus has a function of removing sodium mist remaining in the argon gas.

Japanese Patent Publication No. 3-65877

  1 and 2 of Patent Document 1, the sodium condensation type removal apparatus in FIG. 1 is heated to a high temperature near the inlet of the apparatus by a heating device such as an electric heater. Therefore, the sodium captured by the mesh (filler) is heated by the heating device when returning to the reactor vessel and re-evaporates, and the sodium concentration in the argon gas in the sodium condensation type removal device becomes high. As a result, there was a problem that the sodium collection efficiency deteriorated.

  The objective of this invention is to raise the sodium collection efficiency of a sodium condensation type removal apparatus.

  The present invention includes a container containing a filler for removing sodium, an inlet pipe for supplying a gas containing sodium attached to the container on the upper side with respect to the filler in the container, and filling in the container An outlet pipe attached to the container on the lower side with respect to the material for discharging the gas from which sodium has been removed and a heating device for heating the inlet pipe are provided.

  ADVANTAGE OF THE INVENTION According to this invention, it is possible to raise the sodium collection efficiency of a sodium condensation type removal apparatus.

It is explanatory drawing which showed the structural example of the cover gas type | system | group of a fast breeder reactor. It is explanatory drawing which showed the structural example of the sodium condensation type removal apparatus. Example 1 It is explanatory drawing which showed the structural example of the sodium condensation type removal apparatus. (Example 2) It is explanatory drawing which showed the structural example of the sodium condensation type removal apparatus. (Example 3) It is explanatory drawing which showed the structural example of the sodium condensation type removal apparatus. Example 4

  The present invention relates to a sodium condensation type removal apparatus for capturing sodium vapor contained in a cover gas covering a free liquid surface of liquid sodium in a sodium handling facility.

  FIG. 1 shows a configuration example of a cover gas system of a fast breeder reactor. In order to remove the heat generated in the reactor core 2 in the reactor vessel 1, the coolant sodium 3 is filled with a free liquid surface, and this coolant sodium is about 500 ° C. during the reactor operation. It becomes hot. The cover gas space 4 on the free liquid surface of the coolant sodium 3 is filled with argon gas, which is an inert gas, as a cover gas from the standpoint of preventing sodium oxidation.

During the reactor operation, sodium mist and vapor are transferred into the cover gas from the free liquid surface of the coolant sodium 3. The cover gas also contains radioactive argon ( ⁴¹ Ar) generated by the activation of argon and fission products (FP) such as xenon and krypton when the fuel is damaged. Therefore, for the purpose of removal of sodium components, attenuation of ⁴¹ Ar and removal of FP, a mist trap 6, a sodium condensation type removal device 19, a rare gas removal / recovery facility 14 and a ⁴¹ Ar attenuation tank 16 are provided, and the compressor 15 Is closed loop operation.

  In FIG. 1, the cover gas space 4 on the free liquid surface of the coolant sodium 3 in the reactor vessel 1 is filled with argon gas containing sodium mist and vapor. This argon gas is led from the outlet of the reactor vessel 1 to the mist trap 6 by a passage (pipe) 5 and after the mist-like sodium is removed, it passes through the sodium condensing removal device inlet pipe 17 to remove the sodium condensing type. Guided to the top of the device 19. The argon gas is heated to about 500 ° C. by the electric heater 18 before flowing into the sodium condensation type removing device 19. The sodium vapor in the argon gas is removed by condensing on the surface of the mesh 20. The removed liquid sodium is returned to the reactor vessel 1 through the drain pipe 22 that has fallen due to its own weight against the surface tension of the mesh portion and has a drain gradient. The drain pipe 22 is provided with a drain valve 12 for adjusting the flow rate of the drain. On the other hand, the argon gas from which the sodium vapor has been removed flows out of the apparatus through an outlet attached to the lower part of the sodium condensation type removal apparatus 19.

  FIG. 2 is an enlarged view of the sodium condensation type removal apparatus. The sodium condensation type removal apparatus includes a mesh 20 that is a filler for removing and capturing sodium vapor, a container containing the filler, and a reactor vessel attached to an upper container with respect to the filler in the container. Sodium condensation removal device inlet piping 17 into which the cover gas flows from, and a sodium condensation removal device attached to the lower container with respect to the filler in the container and from which the cover gas from which sodium vapor has been removed flows out An electric heater (heating device) that is provided on the outer wall of the outlet pipe 21 and the sodium condensation type removal device inlet pipe 17 and heats the cover gas flowing into the sodium condensation type removal device 19 to vaporize sodium contained in the cover gas. 18 and a drain arrangement provided at the bottom of the sodium condensation removal device 19 for draining sodium captured by the mesh 20. It is equipped with a 22. The upper space and the lower space of the mesh 20 communicate with the sodium condensation type removal device inlet pipe 17 and the sodium condensation type removal device outlet pipe 21 respectively. Further, the container containing the filler has a cylindrical shape, and the AA cross section of the container is shown on the right side of FIG.

  In the present embodiment, the cover gas from the reactor vessel 1 is heated to about 500 ° C. by an electric heater 18 attached to the sodium condensing removal device inlet pipe 17. The electric heater 18 vaporizes sodium contained in the cover gas. The heated cover gas flows into the upper space of the sodium condensation type removal device 19 from the sodium condensation type removal device inlet pipe 17. The cover gas that has flowed into the removal device flows downward and is cooled when passing through the mesh 20, and sodium contained in the cover gas is removed in a liquid state. The cover gas from which the sodium has been removed flows out of the removal device from the sodium condensation removal device outlet pipe 21. On the other hand, sodium trapped by the mesh 20 is dropped to the bottom of the sodium condensation type removal device 19 and returned to the vessel in which liquid sodium is stored, such as a reactor vessel, through the drain pipe 22.

  In this way, the inlet pipe for supplying the gas containing sodium attached to the upper container with respect to the filler in the container, and the sodium attached to the lower container with respect to the filler in the container By providing an outlet pipe for discharging the removed gas and a heating device for heating the inlet pipe, the heating device is positioned above the filler. Therefore, when sodium captured by the filler is returned to the reactor vessel, it can be prevented from being heated again by the heating device and re-evaporated. And it is possible to raise the sodium collection efficiency of a sodium condensation type removal apparatus.

  FIG. 3 is an enlarged view of the sodium condensation type removal apparatus. In FIG. 3, only a different part from FIG. 2 is demonstrated. The sodium condensed removal device of this embodiment is different from the first embodiment in that a temperature control mechanism 23 that controls the temperature of the mesh 20 is provided on the outer side surface of the sodium condensed removal device 19. The temperature control mechanism 23 is configured by an electric heater, a cooling unit in which the side surface of the sodium condensation type removing device 19 is surrounded by a cooling jacket, or a coolant flows through the cooling jacket, or a combination of an electric heater and a cooling unit. The AA cross section of the temperature control mechanism 23 is shown on the right side of FIG.

  In the present embodiment, the cover gas from the reactor vessel is heated to about 500 ° C. by the electric heater 18 attached to the sodium condensing removal device inlet pipe 17. The sodium contained in the cover gas is vaporized, and the cover gas flows into the sodium condensed removal device 19 from the sodium condensed removal device inlet pipe 17. The temperature control mechanism 23 sets the temperature on the upper side (inlet piping side) of the mesh 20 to about 130 ° C., and sets the temperature on the lower side (outlet piping side) of the mesh 20 to about 400 ° C. That is, the temperature control mechanism 23 sets the temperature distribution in the vertical direction of the mesh. Then, the cover gas is cooled when passing through the mesh 20, and sodium contained in the cover gas is removed in a liquid state. The cover gas from which the sodium has been removed flows out of the removal device from the sodium condensation removal device outlet pipe 21. On the other hand, the sodium captured by the mesh 20 is dropped to the bottom of the sodium condensation removing device 19 and is returned from the drain pipe 22 to a vessel such as a reactor vessel in which liquid sodium is stored. In this way, argon gas containing sodium vapor is introduced from the top of the sodium condensation-type removal device 19 and the argon gas from which sodium has been removed is caused to flow out from the bottom of the sodium condensation-type removal device 19, so that the captured sodium is heated again. It can be recovered without re-evaporation, and the efficiency of sodium aggregation capture can be increased. Moreover, it is possible to liquefy sodium efficiently by providing a temperature control mechanism.

  FIG. 4 is an enlarged view of the sodium condensation type removal apparatus. In FIG. 4, only a different part from FIG. 3 is demonstrated.

  The sodium condensation type removal apparatus of the present embodiment is different from the second embodiment in the shape of the mesh 24. Specifically, the upper surface of the filler (mesh 24) facing the gas inlet port where the sodium condensation type removal apparatus inlet pipe 17 is joined to the container has a downward slope from the center of the upper surface toward the container side surface.

  In the present embodiment, the cover gas from the reactor vessel is heated to about 500 ° C. by the electric heater 18 attached to the sodium condensing removal device inlet pipe 17. After the sodium contained in the cover gas is vaporized, the cover gas flows into the sodium condensed removal device 19 from the sodium condensed removal device inlet pipe 17. The cover gas flowing into the removal device is cooled when passing through the mesh 24, and sodium contained in the cover gas is removed in a liquid state. As described in the second embodiment, the temperature of the mesh 24 is controlled by the temperature control mechanism 23. The cover gas from which the sodium has been removed flows out of the removal device from the sodium condensation removal device outlet pipe 21. On the other hand, the sodium captured by the mesh 24 is dropped to the bottom of the sodium condensation type removal device 19 and returned from the drain pipe 22 to a vessel in which liquid sodium such as a reactor vessel is stored. In this way, argon gas containing sodium vapor is introduced from the top of the sodium condensation-type removal device 19 and the argon gas from which sodium has been removed is caused to flow out from the bottom of the sodium condensation-type removal device 19, so that the captured sodium is heated again. It can be recovered without re-evaporation, and the efficiency of sodium aggregation capture can be increased.

  Further, the upper surface of the filler (mesh 24) facing the gas inflow port where the sodium condensing removal device inlet pipe 17 is joined to the container has a downward slope from the center of the upper surface toward the container side surface. Therefore, the sodium captured by the mesh 24 flows along the inclination of the mesh 24 toward the side surface to which the temperature control mechanism 23 is attached. And it flows to the bottom part of the sodium condensation type removal apparatus 19 along the side wall of the sodium condensation type removal apparatus 19. The temperature of the side surface of the sodium condensation type removal device 19 is controlled by the temperature control mechanism 23 as compared to the center side. Therefore, it is possible to prevent sodium from being solidified inside the mesh 24 and being blocked by positively flowing sodium to the side of the removing device.

  In this embodiment, the temperature control mechanism 23 and the mesh 24 are combined, but only the mesh 24 may be used.

  FIG. 5 is an enlarged view of the sodium condensation type removal apparatus. In FIG. 5, only a different part from FIG. 4 is demonstrated.

  The sodium condensation type removal apparatus of the present embodiment includes an electric heater 25 that is a heating device at the bottom of the sodium condensation type removal apparatus 19 and outside the drain pipe 22. The electric heater 25 controls the temperature of the bottom of the sodium condensation removing device 19 and the drain pipe 22 to a temperature at which sodium does not solidify (about 100 ° C.). And the electric heater 25 can prevent that the sodium dripped at the bottom part of the sodium condensation type removal device 19 and the sodium flowing into the drain pipe 22 are solidified and cannot be recovered.

  In the present embodiment, the temperature control mechanism 23, the mesh 24, and the electric heater 25 are combined, but only the electric heater 25 may be used.

DESCRIPTION OF SYMBOLS 1 Reactor vessel 2 Reactor core 3 Coolant sodium 4 Cover gas space 5, 7 Piping 6 Mist trap 8, 19 Sodium condensation type removal device 9, 20, 24 Mesh 10, 18, 25 Electric heater 12 Drain valve 14 Recovery equipment 15 Compressor 16 Damping tank 17 Sodium condensing removal device inlet piping 21 Sodium condensing removal device outlet piping 22 Drain piping 23 Temperature control mechanism

Claims (4)

A container with a filler to remove sodium;
An inlet pipe for supplying a gas containing sodium, attached to the container on the upper side with respect to the filler in the container;
An outlet pipe attached to the container on the lower side with respect to the filler in the container to discharge the gas from which sodium has been removed;
A fast breeder reactor cover gas-based sodium condensation type removal apparatus comprising a heating device for heating the inlet pipe.   2. The fast breeder reactor cover gas-based sodium condensation type removal apparatus according to claim 1, wherein a temperature control mechanism for controlling the temperature of the filler is provided on a side surface of the container.   The upper surface of the filler facing the gas inflow port joined to the container with the inlet pipe has a downward slope from the center of the upper surface toward the container side surface. Fast breeder reactor cover gas-based sodium condensation removal system.   4. The fast breeder reactor cover gas-based sodium condensation type removal apparatus according to claim 1, wherein a heating device is attached to the bottom of the container.

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