JP2000162378A - Concrete cask - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly safe concrete cask not externally discharging radioactive materials out of a canister together with cooling air in the case of rare leakage. SOLUTION: This concrete cask 1 has a container inner cylinder 20 where a canister containing spent nuclear fuel rods inside a main vessel 10 formed with concrete into a cylinder with a bottom is inserted of which upper opening is closed with a closing lid 30. Between the outer surface of the container cylinder 20 and the inner surface of the main vessel 10, a cooling air flow space 16 is formed and this cooling air flow space 16 communicate with outside by way of a cooling air exhaust path 14 and a cooling air supply path 15.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a concrete cask for storing and storing a canister containing spent nuclear fuel and the like.

[0002]

2. Description of the Related Art Spent nuclear fuel used in nuclear power plants must be stored while shielding radiation and dissipating decay heat until reprocessing. A concrete cask is known as one that enables such storage.

As shown in an exploded perspective view of FIG. 3 and a longitudinal sectional view of FIG. 4, a spent nuclear fuel assembly is provided inside a main body container 10 'formed of a concrete having a predetermined thickness and having a closed bottom. A canister 2 'containing a body (fuel rod) is inserted, and the upper opening is hermetically closed by a closing lid 30'.

As shown in an exploded perspective view in FIG. 5, the canister 2 'is constructed by holding a guide tube 2C in a mesh basket 2B disposed in a superposed state in a cylindrical container 2A. Spent nuclear fuel rods (not shown) are inserted into the tube 2B, and the openings at both ends of the container 2A are closed and sealed by the shielding plug 2D, the primary sealing lid 2E, and the secondary sealing lid 2F, and have a columnar shape as a whole. is there.

A plurality of guide spacers 18 which are long in the axial direction are provided on the inner peripheral surface of the main body container 10 'at predetermined intervals in the circumferential direction, and a plurality of support protrusions 1 are provided on the upper surface of the bottom plate 13'.
3A 'is projected, and a cooling air supply passage 15' communicating with the outside is formed at a lower portion, and a cooling air discharge passage 14 'communicating with the outside is formed at an upper portion.

The outer circumference of the canister 2 'is regulated by the guide spacer 18 and is supported by the bottom support projection 13A'. A cooling air flow space 16 'is formed between the outer surface of the canister 2' and the inner surface of the main container 10 '. You. The cooling air supply space 15 'and the cooling air discharge passage 1
4 'is connected, and the air in the cooling air circulation space 16' heated by the heat released from the canister 2 is discharged to the outside from the cooling air discharge passage 14 'and cooled to the cooling air circulation space 16'. Air is supplied from outside via an air supply passage 15 ', and the air flows through the cooling air flow space 16' to cool the canister 2 (natural air cooling).

[0007]

In the concrete cask constructed as described above, the inner surface of the main container 10 'and the outer surface of the canister 2' are connected to the cooling air flow space 16 '.
Therefore, the outer surface of the canister 2 'directly contacts the cooling air. Therefore, if the radioactive substance leaks from the canister 2 ', there is a possibility that the radioactive substance will be discharged to the outside together with the cooling air.

The present invention has been made in view of the above problems, and provides a highly safe concrete cask in which even if a radioactive substance leaks from a canister, it is not released to the outside together with cooling air. The purpose is to do.

[0009]

According to the present invention, there is provided a concrete cask of the present invention, which is formed of a concrete having a predetermined thickness into a cylindrical shape having a bottom and has a cooling air supply passage communicating with the outside at a lower part thereof and an upper part. In a main body container having a cooling air discharge passage communicating with the outside, a bottomed cylindrical metal housing container member having a predetermined cooling air circulation space is inserted, and a canister is provided in the housing container member. Is inserted, the cooling air circulation space and the upper opening of the storage container member are sealed by a sealing lid member fixed to an edge of the main container, and the cooling air heated by the heat released from the canister It is configured such that air in the circulation space is discharged to the outside from the cooling air discharge passage and air is supplied to the cooling air circulation space from the outside through the cooling air supply passage. And said that you are.

[0010] Further, the present invention is characterized in that it is provided with a negative pressure setting device having suction means capable of suctioning the inside of the container member and setting a negative pressure from the outside, and pressure detecting means for detecting the pressure. Features.

[0011]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is an external perspective view of one example of the construction of a concrete cask according to the present invention, and FIG. 2 is a sectional view taken along line AA of FIG.

In the illustrated concrete cask 1, a housing cylinder 20 as a housing container member for housing the canister 2 is installed inside a main body container 10 formed of a concrete having a predetermined thickness into a bottomed cylindrical shape. The canister 2 containing the spent nuclear fuel rods is inserted into the inside 20 and the upper opening is closed by a closing lid 30 as a sealing lid member.

The main body container 10 includes concrete unit blocks (upper blocks 11) stacked in a plurality of stages (three stages).
U, the central block 11M, and the lower block 11L) are fastened by a plurality of vertically extending fastening bolts 51 arranged at predetermined angular intervals in the circumferential direction to form a bottomed cylindrical shape.
A metal lining inner cylinder 12 made of stainless steel or the like is provided on the inner peripheral surface, and a support projection 1 having a predetermined height is provided on a bottom plate 13.
A plurality of 3A are provided. A cooling air discharge passage 14 is formed near the upper end, and a cooling air supply passage 15 is formed at the lower end.

The cooling air discharge passages 14 are holes having a rectangular cross section of a predetermined size and formed to communicate with the inside and outside of the main body container 10, and are provided at four locations at 90 ° intervals in the circumferential direction. .

The cooling air supply passage 15 has a vertical hole 15A formed at the center of the bottom, and a cooling air discharge passage 14 formed on the lower surface of the bottom.
The concave grooves 1 provided at four locations at 90 ° intervals in the circumferential direction as in
5B are formed to communicate with each other.

The number of the cooling air discharge passages 14 and the cooling air supply passages 15 is not limited to four, and the cooling air discharge passages 14 and the cooling air supply passages 15 are displaced in the circumferential direction. It may be set.

The housing cylinder 20 is formed of a metal such as stainless steel having a predetermined thickness and has a bottomed cylindrical shape having an inner diameter capable of housing the canister 2 and having a large-diameter fastening flange 21 at an opening end thereof. The fastening flange 21 is fixedly fastened to the outer end surface of the main body container 10 by a fastening bolt 51 so that the main body container 1
The bottom surface is provided in contact with the support projection 13. In addition, it is desirable that the inner diameter is set as small as possible with respect to the outer peripheral surface of the canister 2 from the viewpoint of heat transfer. Further, the calorific value of the canister 2 is set in consideration of the heat transfer of the part.

A predetermined gap is set between the outer peripheral surface of the housing cylinder 20 and the inner peripheral surface of the main body container 10 to form a cooling air circulation space 16.
Are connected to the outside via a cooling air discharge passage 14 and a cooling air supply passage 15.

The closing cover 30 is formed by projecting a large-diameter fixed flange 32 on the outer end side of a fitting / closing portion 31 fitted into the housing cylinder 20, and the fitting / closing portion 31 fits into the housing cylinder 20. In addition to closing the opening, the fixing flange 32 is
Numerous fixing bolts 52 penetrating the fastening flange 21
The main body container 10 is fastened to the opening side end surface, and is fixed so as to hermetically seal the inside of the housing cylinder 20.

The closing lid 30 is provided with an intake passage 33 communicating the inside and the outside. The intake passage 33 is connected to a negative pressure setting device 60 via a pipe 71.

As shown conceptually in FIG. 2, the negative pressure setting device 60 includes a pressure gauge 61 as pressure detecting means and a valve 6.
2. A filter 63 and an exhauster 64 as suction means are provided. After the exhauster 64 suctions the inside of the housing cylinder 20 to reduce the pressure from the outside with the valve 62 opened, the valve 62 is opened. By closing, the inside of the housing cylinder 20 housing the canister 2 can be maintained at a negative pressure. The filter 63 and the air blower 64 provided downstream of the valve 62 need not be provided in one concrete cask, but may be provided in one set for a plurality of concrete casks. is there.

Thus, in the concrete cask 1 configured as described above, the air flows through the cooling air flow space 16 and dissipates the heat emitted by the canister 2 to the outside. That is, the air in the cooling air circulation space 16 heated by the heat released from the canister 2 is discharged outside from the upper cooling air circulation passage 14, and the cooling air circulation space 16 passes through the cooling air supply passage 15. Air is supplied from the outside, and the air flows through the cooling air circulation space 16 to cool the canister 2 (natural air cooling). In this configuration, since the cooling air circulation space 16 is formed between the outer peripheral surface of the housing cylinder 20 and the inner peripheral surface of the main body container 10, the cooling air does not directly contact the canister 2. Even if the radioactive substance leaks from the canister 2, it is not released to the outside together with the cooling air.

The negative pressure setting device 60 includes a canister 2
Is set and maintained at a negative pressure from the outside from the outside, and the internal pressure is monitored by the pressure gauge 61, so that if a radioactive substance leaks from the canister 2, the radioactive substance is raised by a pressure increase. In addition, even if there is a problem in the airtightness of the housing cylinder 20, the radioactive substance can be prevented from leaking to the cooling air circulation space 16 side, and extremely high safety can be obtained.

The concrete cask 1 of the above configuration example
Is an example in which the cooling air discharge passage 14 and the cooling air supply passage 15 are provided at four locations at 90 ° intervals in the circumferential direction.
The number of the cooling air discharge paths 14 and the number of the cooling air supply paths 15 may be smaller or larger than this.

[0026]

As described above, according to the concrete cask according to the present invention, a cooling air supply passage which is formed of a concrete having a predetermined thickness and has a bottomed cylindrical shape and communicates with the outside at a lower portion and an upper portion are provided. In a main body container having a cooling air discharge passage communicating with the outside, a bottomed cylindrical metal housing container member having a predetermined cooling air circulation space is inserted, and a canister is provided in the housing container member. Is inserted, the cooling air circulation space and the upper opening of the storage container member are sealed by a sealing lid member fixed to the edge of the main container, and the air in the cooling air circulation space heated by the heat released from the canister Is configured to be discharged from the cooling air discharge passage to the outside and to be supplied with air from the outside to the cooling air circulation space via the cooling air supply passage. Cooling air does not come into direct contact with the canister because it is formed between the outer peripheral surface of the storage cylinder and the inner peripheral surface of the main container, and even if radioactive substances leak from the canister, it is discharged to the outside together with the cooling air It will not be done.

[0027] Further, the apparatus is provided with a negative pressure setting device having suction means capable of suctioning the inside of the housing container member and setting a negative pressure from the outside, and pressure detecting means for detecting the pressure. By setting and maintaining the inside of the container member that houses the canister to a negative pressure from the outside and monitoring the internal pressure via pressure detection means, if radioactive material leaks from the canister, the pressure is raised by an increase in pressure. The radioactive substance can be prevented from leaking to the cooling air circulation space side even when there is a problem in the airtightness of the storage container member, and extremely high safety can be obtained.

[Brief description of the drawings]

FIG. 1 is an external perspective view of a configuration example of a concrete cask according to the present invention.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is an exploded perspective view of a concrete cask as a conventional example.

FIG. 4 is a longitudinal sectional view of a concrete cask as a conventional example.

FIG. 5 is an exploded perspective view of the canister.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Concrete cask 2 Canister 10 Main body container 14 Cooling air discharge path 15 Cooling air supply path 16 Cooling air circulation space 20 Housing cylinder (housing container member) 30 Closing lid (sealing lid member) 60 Negative pressure setting device 61 Pressure gauge (Pressure detection) Means) 64 exhaust fan (suction means)

Claims (2)

[Claims] 1. A main body container formed of a concrete having a predetermined thickness in a cylindrical shape with a bottom and provided with a cooling air supply passage communicating with the outside at a lower portion thereof and a cooling air discharge passage communicating with the outside at an upper portion thereof. A metal container member having a bottomed cylindrical shape is inserted with a predetermined cooling air circulation space around,
A canister is inserted into the housing container member, and the cooling air flow space and the upper opening of the housing container member are sealed by a sealing lid member fixed to an edge of the main container, and the heat release of the canister The air in the cooling air circulation space heated by the cooling air is discharged from the cooling air discharge passage to the outside, and air is supplied to the cooling air circulation space from the outside via the cooling air supply passage. A concrete cask characterized by: 2. The apparatus according to claim 1, further comprising a negative pressure setting device having suction means for suctioning the inside of said housing container member and setting a negative pressure from the outside, and pressure detecting means for detecting the pressure. The concrete cask according to claim 1, characterized in that: