JPS63265194A - Sodium removing apparatus of fast breeder reactor - Google Patents

Abstract

PURPOSE:To return sodium adhered to a fuel aggregate to a nuclear reactor, by vertically providing a wind tunnel having a gripper mounted therein and made connectable to a fuel access hole at the lower end part thereof to an in-cell crane and spraying heated inert gas to the wind tunnel. CONSTITUTION:A used fuel aggregate 37 charged in the fuel bucket 32 of an upright mechanism 4 from a reactor core 2 and rises along a bucket guide rail 33 to stop within a fuel access hole 29 in an upright state. Whereupon, the gripper of an in-cell crane 41 falls to grasp the aggregate 37 to move the bucket 32 in the mechanism 4 and subsequently brings the segment of a connection cover 46 into contact with said bucket 32 to bring the lower end part of a wind tunnel 42 and the hole 29 to a hermetically closed state. Subsequently, when a blower 45 and heater 44 are operated, the inert gas allowed to fill a fuel transfer cell 5 becomes high temp. to be supplied to the wind tunnel 42 and sprayed to the aggregate 37 to return sodium adhered to the aggregate 37 to the container 1a of a nuclear reactor through a ramp 30.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a sodium removal device for a fast breeder reactor that removes sodium adhering to spent fuel assemblies.

[Prior Art] Conventionally, the fuel handling system of a fast breeder reactor is as shown in FIG. The fuel packets in the upright mechanism 4 are charged from the reactor core 2 by the fuel exchanger 3, and the fuel packets containing the spent fuel assemblies are
The packet is lifted up via the chain 7 by the packet drive device 6 in the fuel transfer cell 5 and placed into the movable track 9 via the fuel inlet/outlet slope 8, and the swing of the movable track 9 moves the fuel to the slope 11 of the relay tank 10 outside the fuel reactor. After being stopped at the position shown in FIG. 1, the packet is suspended via a chain 7 by the packet drive device 6 and charged into the fuel external relay tank 10.

Next, a gripper (not shown) of an in-cell crane 12 provided horizontally movably within the fuel transfer cell 5 is lowered to grasp the spent fuel assembly from the fuel packet and pull it up into the in-cell crane 12. Crane 1
2 to the left and stopped above the rotary cleaning device 14 installed underground between the fuel transfer cell 5 and the adjacent spent fuel storage cell 13, and the in-cell crane 12
The spent fuel assembly gripped by the gripper is inserted into the insertion hole 15.
After that, it is charged into the cleaning tank 16 of the rotary cleaning device 14.

Sodium adhering to the spent fuel assemblies stored in the cleaning tank 16 is removed by spraying a mixed gas consisting of steam from the steam supply pipe 17 and inert gas from the inert gas supply pipe 18. After being converted to sodium oxide, it is washed away with pure water from the pure water tank 19. The generated cleaning waste liquid is stored in the waste liquid tank 20.

In addition, the inert gas containing sodium and unreacted water vapor is sent to the mist separator 21 and separated.

The spent fuel assembly from which sodium has been removed is transferred to the lower part of the pulling hole 22 by the 180° rotation of the cleaning tank 16, and is transferred to the lower part of the pulling hole 22 by the in-cell crane 23 installed in the spent fuel storage cell 13. It is gripped by a gripper (not shown) and pulled up into the incel crane 23 through the pulling hole 22, and the incel crane 23 moves 8i! to the left! III
and transferred to a water boule (not shown).

On the other hand, new fuel assemblies to be loaded into the reactor core 2 are transported by a trolley 25 running in a tunnel 24 outside the reactor and stopped below the fuel transfer cell 5, and are stopped by an in-cell crane 1.
After being gripped by the gripper No. 2 and pulled up into the incel crane 12 through the new fuel pulling hole, the incel crane 12 is moved to the right and stopped at the position of the relay tank 10 outside the fuel reactor. A new fuel assembly gripped by a gripper is lowered into the M tank 10 and charged into a fuel packet housed in the relay tank 10 outside the fuel reactor. Thereafter, the new fuel assembly loaded into the fuel packet is loaded into the upright mechanism 4 through the reverse process to that described above, and then loaded into the reactor core 2 by the fuel exchanger 3.

[Problems to be Solved by the Invention] However, the above-mentioned sodium removal device for a fuel handling system requires many accessory equipment such as an inert gas supply pipe, a steam supply pipe, a pure water tank, a waste liquid tank, and a mist separator.
The scale of the device increases.

In addition, since washing water is used, it is possible to almost completely remove the sodium attached to the spent fuel, but a large amount of washing waste liquid containing radioactive materials is generated, which increases the equipment cost and cost for processing this waste liquid.
The burden of operating costs will increase.

Therefore, the present invention aims to provide a sodium removal device for a fast breeder reactor that can be downsized and reduce the amount of radioactive waste.

[Means for Solving the Problems] In order to solve the above problems, the present invention includes a liftable gripper for gripping a fuel assembly in a fuel transfer cell above the fuel inlet/outlet hole of the roof slab. An in-cell crane is provided so as to be movable in the horizontal direction, and a wind barrel in which the gripper is housed and whose lower end is connectable to the fuel inlet/out hole is provided vertically on the in-cel crane, and the fuel transfer cell is filled with waste. A blower that heats active gas and blows it onto the spent fuel assembly is mounted on the in-cell crane, and a gas leak prevention structure is provided between the lower end of the wind trunk and the roof slab.

[Function] According to the above means, the sodium adhering to the spent fuel assembly is flowed down by the high temperature inert gas blown by the blower, and is transferred to the wind barrel and fuel inlet/outlet without being scattered in the fuel transfer cell. It is then returned to the reactor vessel.

[Example] Hereinafter, an example of the present invention will be described with reference to FIGS. 1 to 7. In the following description, the same components as those in FIG. 8 are denoted by the same reference numerals, and the description thereof will be omitted.

FIG. 1 is a longitudinal sectional view of a fuel handling system of a fast breeder reactor equipped with a sodium removal device according to a first embodiment.

A vertical fuel inlet/outlet hole 29 communicating with the inside of the fuel transfer cell 5 is provided in the peripheral part of the roof slab 1b, and the lower end of this fuel inlet/outlet 29 is connected to the upper end of the upright mechanism 4 and the inclined path 3.
0, and the fuel inlet/outlet hole 29. The inclined path 30 and the upright mechanism 4 form a fuel transfer path 31 bent in an S-shape. Inside the fuel transfer path 31, a fuel packet 32 is provided.
A packet guide rail 33 is provided to guide the fuel packet 32 in a slidable manner, and the fuel packet 32 is suspended by a chain 35 by a packet drive device 34 provided at the top of the fuel 6 feeding cell 5 so as to be movable up and down. .

A horizontally extending crane rail 36 is installed above the fuel inlet/outlet hole 29 in the fuel transfer cell 5, and the crane rail 36 grips a fuel assembly 37 and lifts the chain using a gripper lifting device 38. An in-cell crane 41 is provided with a gripper 40 that is suspended by a handle 39 and is movable by a traveling device (not shown). The incel crane 41 includes the gripper 40
A wind barrel 42 is installed vertically, and the lower end of the wind barrel 42 extends appropriately above a boat valve 43 that opens and closes the fuel inlet/outlet hole 29. In addition, the in-cell crane 41 is configured to heat the inert gas filled in the fuel transfer cell 5 with a heater 44 and supply it into the wind barrel 42, so that the inert gas filled in the fuel transfer cell 5 is heated and supplied into the wind barrel 42. A blower 45 that blows air is installed.

On the other hand, a connection cover 46 is provided on the boat valve 43 to connect the fuel inlet/outlet hole 29 and the lower end of the wind barrel 42 . As detailed in FIGS. 2 to 4, the connection cover 46 is a pair of bottomed semi-cylindrical shafts attached to a rotating shaft 48 supported on the boat valve 43 with the fuel inlet/outlet hole 29 in between by a bearing 47. A notch 49.50 through which the wind barrel 42 and chain 35 are passed is provided in the ceiling on the contact surface between both segments 46a,
In addition, a heat-resistant rubber 51 is attached to provide a nearly sealed structure. Then, the rotation shaft 48 of the connection cover 46
is linked with a drive device (not shown) provided outside the fuel transfer cell 5.

In addition, in FIG. 1, 52 is a pail of the fuel packet 32, which is provided so as to be able to pass through the fuel assembly 37.

53 is the fuel inlet/outlet hole 29 and the slope 3 in the fuel transfer path 31
The idler is provided at the connection with the fuel packet 32 and guides the chain 35 that pulls the fuel packet 32 to prevent it from sliding against the inner surface of the fuel transfer path 31.

In the sodium removal device having the above configuration, the spent fuel assemblies 37 are charged from the core 2 into the fuel packets 32 in the upright mechanism 4 by the fuel exchange machine 3, and the spent fuel assemblies 37 are charged into the fuel packets 32 in the upright mechanism 4. The fuel packet 32 is lifted up by the chain 35 by the operation of the packet drive device 34, moves up along the packet guide rail 33, and is stopped in the fuel inlet/outlet hole 29 in an upright state. Next, the gripper 40 of the in-cell crane 41 that has been moved above the fuel inlet/outlet hole 29 is lowered to grip the spent fuel assembly 37 inside the fuel packet 31, and then the packet drive device 34 is activated to remove the fuel packet 32. into the upright mechanism 4. At this time, the spent fuel assembly 37 is transferred to the in-cell crane 4.
The fuel inlet/outlet hole 2 is suspended from the gripper 4o of 1.
Stay within 9.

After both segments 46a of the connection cover 46 are brought into contact with each other to connect the lower end of the wind barrel 42 and the fuel inlet/outlet hole 29 in a substantially sealed state, when the blower 45 and the heater 44 are operated, the inside of the fuel transfer cell 5 is The filled inert gas reaches a high temperature and is supplied into the wind barrel 42 as shown by the arrow in FIG. The fuel is blown out from the lower end into the fuel inlet/outlet hole 29. The sodium adhering to the spent fuel assembly 37 flows down and is blown out from the lower end into the fuel inlet/outlet hole 29 along with the inert gas, and then is returned into the reactor vessel la via the slope 3o. Further, the inert gas blown into the fuel inlet/outlet hole 29 is returned into the fuel transport cell 5 through a circulation line (not shown).

After the connection cover 46 is opened, the spent fuel assembly 37 from which the sodium has been removed is lifted into the wind barrel 42 by the lifting of the gripper 40 by the operation of the gripper lifting device 38, and then lifted into the wind barrel 42 by the movement of the in-cell crane 41. etc., to the required location.

On the other hand, a new fuel assembly 37 to be loaded into the core 2 of the reactor vessel 1a is taken out from a new fuel storage cell (not shown), etc., is gripped by the gripper 40 of the in-cell crane 41, pulled up, and stored in the wind barrel 42. be done. Next, after being moved above the fuel inlet/outlet hole 29 by the running of the incel crane 41, it is vertically moved into the fuel inlet/outlet hole 29 by the chain 35 through the connection cover 46 and the boat valve 43, which were previously opened by lowering the gripper 40. The fuel is charged into a fuel packet 32 suspended at a fuel tank. The fuel packet 32 charged with the new fuel assembly 37 is moved to the packet guide rail 3 by the operation of the packet drive device 1f34.
3 and is inserted into the upright mechanism 4. The new fuel assembly 37 in the fuel packet 32 is then loaded into the core 2 by the refueling machine 3.

When the fuel assembly 37 is moved in and out of the reactor vessel 1a, the in-cell crane 41 is moved to the left, and the fuel packet 32 is moved to the packet guide rail in the fuel transfer cell 5 (not shown) by the packet drive device 34. While being guided and pulled up into the fuel transfer cell 5 for inspection and maintenance, the boat valve 43 is closed.

FIG. 5 is a longitudinal sectional view of the sodium removal device of the second embodiment, which differs from the sodium removal device of the first embodiment in that the wind barrel 42 is single layered, and the lower end and fuel inlet/output The main difference is that a connection cover 46 is provided for connection to the hole 29, whereas the wind barrel 421 is made of a double expandable structure and its lower end can be inserted into the fuel inlet/outlet hole 29.

That is, the wind trunk 421 vertically installed on the incel crane 41
An outer tube 14421b is fitted into the inner tube 421a, and as detailed in FIG. 55, it can be smoothly raised and lowered along the inner cylinder 421a. A gripper 4 suspended by a chain 39 is provided in the lower end of the outer cylinder 421b.
0 is attached. Further, a flange-shaped cover 56 is attached to the outside of the lower end of the outer cylinder 421b, as detailed in FIG. 7. The cover 56 is a scattering prevention wall 5 provided on the boat valve 43 surrounding the fuel inlet/outlet hole 29.
This cover 56 is provided with a notch 58 through which the chain 35 suspending the fuel packet 32 is passed. There is. The arrows in FIG. 5 indicate the flow of inert gas.

Since the other configurations and operations are substantially the same as those of the sodium removal device of the first embodiment, the same components and the like are given the same reference numerals and their explanations will be omitted.

In each of the above embodiments, a case has been described in which the fuel transfer path 31 between the in-core fuel delivery position and the fuel transfer cell 5 is bent in an S-shape, but the fuel transfer path is limited to an S-shape. Alternatively, it may be a vertical straight line or an inclined straight line.

[Effects of the Invention] As described above, according to the present invention, sodium adhering to a spent fuel assembly flows down by the high-temperature inert gas blown by the blower, and is removed by the wind without being scattered inside the fuel transfer cell. Since the sodium is returned to the reactor vessel through the shell and the fuel inlet/outlet, the conventional accessory equipment such as inert gas supply pipes and steam supply pipes can be eliminated, making it possible to reduce the scale of the sodium removal equipment. The amount of radioactive waste generated can be dramatically reduced, and the fuel handling system can be simplified, and equipment costs and operating costs for waste treatment can be reduced.

[Brief explanation of drawings]

1 to 7 show embodiments of the present invention. FIG. 1 is a vertical cross-sectional view of a fuel handling system of a fast breeder reactor equipped with a sodium removal device according to the first embodiment, and FIG. FIG. 3 is a longitudinal sectional view of the main parts of the sodium removal device of the first embodiment, FIG. 3 is an enlarged cross-sectional view taken along the line ■I-III in FIG. 6 and 7 are respectively an enlarged sectional view along the line Vl-Vl in FIG. 5, and an enlarged sectional view along the line ■-■ in FIG. 8. FIG. 2 is a longitudinal sectional view of the fuel handling system of the fast breeder reactor.

Claims (1)

[Claims] An in-cell crane equipped with a liftable gripper for gripping a fuel assembly is installed in a fuel transfer cell above the fuel inlet/outlet hole of the roof slab so as to be movable in the horizontal direction. A wind barrel that can be connected to an inlet/outlet hole is installed vertically on the in-cell crane, and a blower that heats the inert gas filled in the fuel transfer cell and blows it onto the spent fuel assembly is mounted on the in-cel crane. A sodium removal device for a fast breeder reactor, characterized in that a gas leak prevention structure is provided between the lower end of the wind barrel and the roof slab.