JP2001013295A - Radioactive waste storage facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a radioactive waste storage facility of which integrity can be secured for a long period. SOLUTION: A cell room 22 communicates with an outside air introduction passage equipped with an outside air inlet 32, a lower plenum 24 located below housing tubes 36 and a cooling air exhaust passage equipped with an air outlet 34 and has an upper plenum 28 located below a ceiling slug 40. A side-wall flow channel 56 for cooling a concrete side wall 50 is formed between it and a plate 54 for forming the side-wall flow channel. The housing tubes containing radioactive wastes and the concrete side wall are cooled by natural ventilation derived from the convection in the cell room generated by the heat emitted from the radioactive substances stowed in each of the housing tubes 36. A plate 60 for forming a ceiling flow channel is placed opposite to the inner face of the ceiling slug, and a ceiling flow channel 62 communicating with the side- wall flow channel is formed between the ceiling slug and the plate 60 for forming the ceiling flow channel. Partitions that extend from the lower plenum 24 toward the upper plenum 28 are formed in the side-wall flow channel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a radioactive waste storage facility.

[0002]

2. Description of the Related Art As described in Japanese Patent Publication No. 1-53760, for example, waste liquid from a nuclear fuel reprocessing plant is packaged as a vitrified material, and the vitrified material then generates heat due to the collapse of radioactive material. Cooling in storage facilities. 6 and 7 show a conventional typical natural ventilation type storage facility, and FIG. 8 shows a flow of ventilation including a cell room. This storage facility 1 has a concrete side wall 1
4 and a cell room 2 surrounded by a ceiling slug 6,
In the cell chamber 2, a plurality of storage pipes 4 each storing the vitrified body 3 are fixed to a ceiling slag 6 that partitions the cell chamber 2 from an upper transfer chamber 5 and hang downward. I have. In addition, as shown in FIG.
By arranging the outer tube 7, the outer tube 7 and the storage tube 4
And an annular space 8 is formed between the two, and this annular space 8 is used as a cooling air passage. The concrete side wall 14 is provided with a side wall passage forming plate 15 facing the inner surface of the concrete side wall, and a side wall passage 16 for cooling the concrete side wall is provided between the concrete side wall 14 and the side wall passage forming plate 15. Is formed.

In such a storage facility 1, the decay heat of the vitrified material 3 stored in the storage tube 4 heats the air in the surrounding annular space 8 through the storage tube 4, and accordingly spontaneously occurs. Convection, in which the air in the annular space 8 rises,
The convection in the annular space 8 creates a flow of air that takes air from the outside air inlet into the air supply shaft 10. That is, the air introduced into the air supply shaft 10 enters the annular space 8 from the lower plenum 11 below the storage tube 4 as shown by an arrow in FIG. At the same time, it rises in the side wall flow path 16, then enters the exhaust shaft 13 through the upper plenum 12, and after rising up the exhaust shaft 13, is discharged outside through the air outlet. For this reason, in the storage facility 1, as long as the vitrified body 3 in the storage tube 4 generates heat, the annular space 8 which occurs spontaneously occurs.
The storage pipe 4 containing the vitrified body 3 and the concrete side wall 14 can be cooled by natural ventilation by convection.

[0004]

However, in such a conventional storage facility 1, the vitrified body 3 itself can be cooled by natural ventilation, but is heated by the decay heat of the vitrified body 3. There is a problem that the cooling of the concrete structure around the cell chamber 2 is insufficient.

More specifically, the first problem is that the ceiling slag 6 is insufficiently cooled. In the ceiling, there is usually insulation 1
9 is installed, but there is almost no heat escape to the transfer chamber 5 located above the ceiling slag 6, so it is difficult to prevent the ceiling slag 6 from overheating by the heat insulating material 19. Further, as shown in FIG. 8, since a part of the heated cooling air generates a circulating flow in the side wall flow path 16, the cooling function of the cooling air is more effective than when the cooling air flows through the side wall flow path 16 one-through. Will be insufficient.

Second, as shown in FIG. 9, after the cooling air is taken in from the outside air inlet and reaches the lower plenum 11, it flows unevenly when passing through the side wall flow passage 16 in the cell chamber 2. Become. In other words, the concrete side wall near the air supply shaft 10 becomes a blind spot, and the air flow to this area decreases,
As a result, the concrete side walls in this area are overheated. Third, as shown in FIG. 10, the cooling flow rate decreases due to the pressure loss of the cooling air in the cooling air outlet passage 13. Since the vitrified material also generates radiation along with heat for a long period of time, the cooling air inlet passage 10 and the cooling air outlet passage 13 are respectively provided to shield around the cell chamber 2 in a manner as shown in FIG. Inlet shield plate 17 and outlet shield plate 1
8 are alternately arranged in a maze shape. FIG. 10 shows the flow of the cooling air in the passage by the shield plates 17 and 18. As shown in FIG. 10, the direction of the cooling air is forcibly changed five times, which causes a pressure loss and makes it difficult to secure a cooling air flow rate.

[0007] In the first place, the storage facility for radioactive waste is required to safely store the vitrified material 3 for a very long time until the radioactivity level is attenuated to a certain level. Ensuring soundness is a very important issue.

In this respect, the allowable heat-resistant temperature of the concrete constituting the building structure of the storage facility is usually 65 ° C., and it can be said that preventing the concrete from overheating is indispensable for ensuring the long-term soundness of the storage facility.

[0009] In view of the above-mentioned problems, it is an object of the present invention to store radioactive waste that can ensure long-term soundness by sufficiently and uniformly cooling the radioactive waste and the surrounding concrete structure. To provide facilities.

[0010]

Means for Solving the Problems In order to solve the above problems,
In the storage facility for radioactive waste of the present invention, a plurality of storage pipes are juxtaposed in a cell room which is surrounded on all sides by concrete side walls, and the upper side is partitioned by concrete ceiling slag, and this cell room has an outside air inlet. A lower plenum that communicates with the outside air introduction passage and is located below the plurality of storage pipes, and an upper plenum that communicates with a cooling air discharge passage having an air outlet and is located below the ceiling slag. A side wall channel forming plate is provided facing the inner surface of the concrete side wall, and a side wall channel for cooling the concrete side wall is formed between the concrete side wall and the side wall channel forming plate. By the natural ventilation by the convection in the cell room generated by the heat generated by the stored radioactive waste, the storage pipe containing the radioactive waste and the concrete side wall are cooled. In the storage facility for radioactive waste, the ceiling slag is provided with a ceiling flow path forming plate facing the inner surface of the ceiling slag, and the side wall flow path is communicated between the inner surface of the ceiling slag and the ceiling flow path forming plate. To form a ceiling channel
The side wall passage is provided with a partition extending from the lower plenum toward the upper plenum.

In order to solve the above problems, a radioactive waste storage facility according to the present invention has a plurality of storage pipes juxtaposed in a cell room surrounded on all sides by concrete side walls and upwardly partitioned by concrete ceiling slag. The cell chamber communicates with an outside air introduction passage having an outside air inlet and is located below the plurality of storage pipes, and a cooling air discharge passage having an air outlet and is located below the ceiling slag. A side wall channel forming plate is provided on the concrete side wall facing the inner surface of the concrete side wall, and a side wall channel for cooling the concrete side wall is provided between the concrete side wall and the side wall channel forming plate. Is formed, and the radioactive waste is removed by natural convection in the cell chamber generated by heat generated by the radioactive waste stored in each storage tube. In a radioactive waste storage facility that cools a storage pipe and a concrete side wall, an air flow restrictor is formed in the side wall flow path formed between the concrete side wall and the side wall flow path forming plate on the side of the cooling air discharge passage. This is a configuration provided with means.

In order to solve the above-mentioned problems, a radioactive waste storage facility of the present invention has a plurality of storage pipes juxtaposed in a cell room which is surrounded on all sides by concrete side walls and has an upper part partitioned by concrete ceiling slag. The cell chamber is located below the plurality of storage pipes and has a lower plenum communicating with an outside air introduction passage having an outside air inlet, and a cooling air discharge passage located below a ceiling slag and having an air outlet. An upper plenum communicating therewith, the cooling air discharge passage extending upwardly from the ceiling slag and proximate to a concrete proximal side wall of the cell chamber, and extending upwardly and distally of the cell chamber. A cooling air discharge passage having a plurality of shielding plates projecting inward from an inner wall of each of the concrete proximal and distal sidewalls. The storage pipe containing the radioactive waste and the concrete around the cell chamber are cooled by natural ventilation by convection in the cell chamber generated by the heat generated by the radioactive waste stored in each storage pipe. A radioactive waste storage facility wherein cooled air from the upper plenum is deflected upwardly by the inner wall of the concrete distal sidewall toward the air outlet in the cooling air discharge passage. A shielding plate at a lower position is provided on the inner wall of the concrete proximal side wall.

According to the storage facility of the present invention, the cooling air flowing into the cell chamber from the lower plenum flows through the side wall flow path together with the plurality of storage pipes in a manner of natural ventilation, thereby cooling the concrete side wall from the inner wall. be able to. At this time, the air flows as one through through the side wall passage from the lower plenum toward the upper plenum by the partition provided in the side wall passage, and it is possible to prevent the circulating flow in the side wall passage which occurs in the related art. Further, the air can pass through the ceiling flow passage communicating with the side wall flow passage, and cool the ceiling slab from its inner wall. Thus, not only the radioactive waste but also the concrete side walls and the ceiling slag can be sufficiently cooled.

According to the storage facility of the present invention, the cooling air flowing into the cell chamber from the lower plenum flows through the side wall flow path together with the plurality of storage pipes in a manner of natural ventilation to cool the concrete side wall from the inner wall. be able to. At this time, since the flow rate of the air flowing in the side wall flow path on the side of the cooling air discharge passage is restricted by the air flow restriction means, the side wall flow path on the side of the outside air introduction passage where no such air flow restriction means is provided. Between the air flowing inside,
Achieving a uniform flow rate can prevent uneven cooling of concrete.

According to the storage facility of the present invention, the cooling air flowing into the cell chamber from the lower plenum can cool the plurality of storage pipes by natural ventilation. At this time,
Air entering the cooling air discharge passage from the upper plenum is deflected by the inner wall of the concrete distal side wall and flows upward in the cooling air discharge passage toward the air outlet.
At that time, since the lowermost shielding plate is provided on the inner wall of the concrete proximal side wall, the deflected air flows as it is over the lowermost position shielding plate along the inner wall of the concrete distal side wall. Can be. Therefore, by minimizing the occurrence of pressure loss of air due to the shielding plate in the cooling air discharge passage, the shielding plate is able to sufficiently secure the flow rate of cooling air while ensuring the function of shielding radiation that generates radioactive waste. can do.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below in detail with reference to FIG. Storage facility 2
1A, as can be understood from FIG. 1 (a), similarly to the conventional case, the cell room 22 has a cell room 22 surrounded on all sides by a concrete side wall 50 and an upper part partitioned by a concrete ceiling slag 40. Multiple storage tubes 36 inside
Are juxtaposed. An air supply shaft 2 is provided below the storage chamber 36.
The lower plenum 24 leading to 6 and the upper plenum 28 leading to the exhaust shaft 30 are formed below the ceiling slag 40. The exhaust shaft 30 includes a concrete sidewall 70 extending upwardly from the ceiling slug 40 on a proximal side of the cell chamber 22 and a concrete sidewall 72 on a distal side of the cell chamber 22.
And At the upper end of the air supply shaft 26, the outside air inlet 3
2 is provided, and at the level of the upper plenum 28, an inlet shielding plate 52 is provided so as to properly shield radiation generated from the storage tube 36 from leaking outside. On the other hand, an air outlet 34 is provided at the upper end of the exhaust shaft 30.
At the level of the upper plenum 28, an outlet shield plate 53 is provided for the same purpose as the inlet shield plate 52. As a result, the supply shaft 2 through the outside air inlet 32
The air taken into the 6 enters the upper plenum 28 from the lower plenum 24 through the cell chamber 22 as shown by the arrow, and from the upper plenum 28 through the exhaust shaft 30 to the upper end of the exhaust shaft 30. Air outlet 3
Then, the plurality of storage tubes 36 arranged in the cell chamber 22 are cooled by the flow of the cooling air. The ceiling slug 40 that partitions the cell chamber 22 and the transfer chamber 38 has through holes 4 communicating with the storage tubes 36.
0a is formed, and the cell chamber 22 is formed through the through hole 40a.
The vitrified body 42 is stored in and taken out of each of the storage tubes 36 therein.

In addition, an outer tube which forms an annular space communicating with the lower plenum 24 and the upper plenum 28 is eliminated around each of the storage tubes 36, unlike the related art.

A side wall channel forming plate 54 is disposed on the concrete side wall 50 so as to face the inner surface of the concrete side wall, and a side wall channel 56 for cooling the concrete side wall is provided between the concrete side wall 50 and the side wall channel forming plate 54. Is formed. Further, as clearly shown in FIGS. 1B and 1C, the side wall flow path 56 is provided with a rib 58 extending from the lower plenum 24 toward the upper plenum 28, and the side wall flow path 56 is separated from the lower plenum 24. It is partitioned into individual channels extending toward the upper plenum 28. The ceiling slag 40 is provided with a ceiling channel forming plate 60 facing the inner surface of the ceiling slab,
A ceiling channel 62 communicating with the side wall channel 56 is formed between the inner surface of the ceiling slag and the ceiling channel forming plate 56. 60a
And 54a, both the ceiling channel forming plate 60 and the side wall forming plate 54 extend to near the inlet of the exhaust shaft 30.

According to the storage facility according to the embodiment constructed as described above, as long as the vitrified body 42 stored in the storage tube 36 generates heat, as in the related art, natural heat is generated by its decay heat. A convection in which the air in the cell chamber 22 rises is generated, and natural ventilation induced by the convection, that is, from the introduction passage formed by the supply shaft 26 and the lower plenum 24 from the outside air inlet 32, the cell chamber 22 is As described above, the plurality of storage tubes 36 arranged in the cell chamber 22 are cooled by the flow of the cooling air discharged from the air outlet 34 to the outside through the exhaust passage formed by the upper plenum 28 and the exhaust shaft 30. That is, the air that has entered the air supply shaft 26 absorbs the heat of the storage pipe 36 from the lower plenum 24 while the cell chamber 22
Up, then upper plenum 28, exhaust shaft 3
0, and goes up through the air outlet 34 after going up the exhaust shaft 30.

At this time, the air flows as one through through the side wall passage 56 from the lower plenum 24 to the upper plenum 28 by the rib 58 provided in the side wall passage 56, and the air in the side wall passage 56 generated by the prior art. A circulating flow can be prevented. Further, the air passes through the ceiling channel 62 communicating with the side wall channel 56 and can cool the ceiling slag 40 from its inner wall. Thereby, not only the vitrified body 42 as the radioactive waste but also the concrete side wall 50 and the ceiling slag 40 can be sufficiently cooled.

Another embodiment of the present invention will be described below. The same elements as those in the first embodiment are denoted by the same reference numerals, and the description thereof will not be repeated. I do.

A second embodiment of the present invention will be described below in detail with reference to FIGS.

The present embodiment is characterized in that the air flow restricting means 6 is provided in a side wall passage 56 formed between the concrete side wall 50 on the cooling air discharge passage 30 side and the side wall passage forming plate 54.
4 is provided. As can be understood from FIG. 2A, the air flow restricting means 64 is disposed over a region that is substantially half the cross-sectional area of the side wall flow path 56. The installation height of the air flow restricting means 64 is preferably at a level below the concrete side wall 50.

In FIG. 2B, the air flow restricting means 6
4 comprises a perforated plate 64b arranged so as to intersect with the flow of the cooling air in the side wall flow path 56. On the other hand, FIG.
, The air flow restricting means 64 is provided with a gap adjusting plate 64 arranged along the flow of the cooling air in the side wall flow path 56.
c. In any case, the area porosity is preferably about 20% to 50%. According to such an air flow restricting means 64, as shown in FIG. 3, a conventional blind spot is formed between the side wall passage 56 on the side of the cooling air discharge passage 30 and the side wall passage 56 on the side of the cooling inlet passage 26. It becomes possible to realize a uniform air flow rate in the side wall flow path, including the concrete side wall close to the air supply shaft side.

A third embodiment of the present invention will be described below in detail with reference to FIGS. The cooling air discharge passage 30 extends upward from the ceiling slag 40 and is located on the concrete proximal side wall 70 located on the proximal side of the cell chamber 22.
And a concrete distal side wall 72 extending upward and located on the distal side of the cell chamber 22.
No. 0 has a plurality of shielding plates 53 which protrude inward from the inner wall of each of the concrete proximal and distal side walls 70, 72, and alternately upward. The present embodiment is characterized in that the lowermost shielding plate among the plurality of shielding plates 53 is provided on the inner wall of the concrete proximal side wall 70.

As shown in FIG. 4, such a shielding plate 53 is provided.
According to the arrangement, when the storage pipe 36 and the concrete structure are cooled in the cell chamber 22 and the air reaching the upper plenum 28 flows into the exhaust shaft 30, the air is deflected by the inner wall of the concrete distal side wall 72. Then, the air flows upward in the exhaust shaft 30 toward the air outlet 34. At this time,
The bottom shield 53 is provided on the concrete proximal side wall 70 so that deflected air can flow past the bottommost shield along the inner wall of the concrete distal side wall 72. Becomes Therefore, the pressure loss of excess air due to the shielding plate 53 in the exhaust shaft 30 is prevented, and as a result, a sufficient flow rate of the cooling air can be secured.
According to a test example, the conventional five air flow redirection (see FIG. 11) was reduced to three redirection, resulting in about 15% cooling air flow, about 10% vitrification and concrete temperature. ° C was confirmed to decrease. In addition, as shown in FIG. 5, radiation from radioactive waste can be sufficiently shielded by a shielding plate 53 arranged in a maze shape as in the related art.

Although the embodiments of the present invention have been described in detail, various changes and modifications can be made within the scope of the present invention described in the claims. For example, the radioactive waste is not limited to the vitrified waste, and the storage facility of the present invention can be applied to any radioactive waste as long as it is cooled and stored in the same manner as in the present embodiment. It is possible.

[0027]

As described in detail above, according to the storage facility of the present invention, not only radioactive waste but also the concrete structure of the facility is sufficiently and uniformly cooled by natural ventilation, whereby the facility can be cooled. Long-term soundness can be achieved.

[Brief description of the drawings]

FIG. 1A is a schematic sectional view of a storage facility according to a first embodiment of the present invention, and FIG.
FIG. 1C is a cross-sectional view taken along the line AA in FIG.
FIG. 2 is an enlarged view of a portion B in FIG.

FIG. 2A is a view corresponding to FIG. 1B of a storage facility according to a second embodiment of the present invention, and FIG.
(B) and (c) are each an enlarged view of a part C of FIG. 2 (a).

FIG. 3 is a diagram showing a flow of cooling air inside a storage facility according to a second embodiment of the present invention.

FIG. 4 is a partial perspective view around a cooling air outlet of a storage facility according to a third embodiment of the present invention.

FIG. 5 is a view similar to FIG. 4 showing a state of refraction and reflection of radiation around a cooling air outlet of a storage facility according to a third embodiment of the present invention.

6 (a) is a schematic sectional view of a conventional storage facility, and FIG. 6 (b) is a sectional view taken along line AA of FIG. 6 (a).

FIG. 7 is a cross-sectional view showing a floor support structure of a storage pipe adopted in a conventional storage facility.

FIG. 8 is a view similar to FIG. 3, showing the flow of cooling air around a concrete side wall inside a conventional storage facility.

FIG. 9 is a diagram showing the entire flow of cooling air inside a conventional storage facility.

FIG. 10 is a partial perspective view around a cooling air outlet of a conventional storage facility, and is similar to FIG.

FIG. 11 is a view showing a state of refraction and reflection of radiation around a cooling air outlet of a conventional storage facility, and is similar to FIG. 5;

[Explanation of symbols]

 Reference Signs List 20 storage facility 22 cell room 24 lower plenum 26 air supply shaft 28 upper plenum 30 exhaust shaft 32 outside air inlet 34 air outlet 36 storage tube 38 transfer chamber 40 ceiling slug 42 vitrified body 50 concrete side wall 52 inlet shield plate 53 outlet shield plate 54 Side wall channel forming plate 56 Side wall channel 58 Rib 60 Ceiling channel forming plate 62 Ceiling channel 64 Air flow restrictor 70 Concrete proximal side wall 72 Concrete distal side wall

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[Procedure amendment]

[Submission date] August 18, 1999 (1999.8.1)
8)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Brief description of drawings

[Correction method] Change

[Correction contents]

[Brief description of the drawings]

FIG. 1 (a) is a schematic sectional view of a storage facility according to a first embodiment of the present invention.

FIG. 1 (b) is a cross-sectional view taken along line AA of FIG. 1 (a).

FIG. 1 (c) is an enlarged view of a portion B in FIG. 1 (b).

FIG. 2 (a) is a view corresponding to FIG. 1 (b) of a storage facility according to a second embodiment of the present invention.

FIG. 2 (b) is an enlarged view of a part C of FIG. 2 (a).

FIG. 2 (c) is an enlarged view of a portion C of FIG. 2 (a).

FIG. 3 is a diagram showing a flow of cooling air inside a storage facility according to a second embodiment of the present invention.

FIG. 4 is a partial perspective view around a cooling air outlet of a storage facility according to a third embodiment of the present invention.

FIG. 5 is a view similar to FIG. 4 showing a state of refraction and reflection of radiation around a cooling air outlet of a storage facility according to a third embodiment of the present invention.

FIG. 6 (a) is a schematic sectional view of a conventional storage facility.

FIG. 6 (b) is a cross-sectional view taken along line AA of FIG. 6 (a).

FIG. 7 is a cross-sectional view showing a floor support structure of a storage pipe adopted in a conventional storage facility.

FIG. 8 is a view similar to FIG. 3, showing the flow of cooling air around a concrete side wall inside a conventional storage facility.

FIG. 9 is a diagram showing the entire flow of cooling air inside a conventional storage facility.

FIG. 10 is a partial perspective view around a cooling air outlet of a conventional storage facility, and is similar to FIG.

FIG. 11 is a view showing a state of refraction and reflection of radiation around a cooling air outlet of a conventional storage facility, and is similar to FIG. 5;

DESCRIPTION OF SYMBOLS 20 Storage facility 22 Cell room 24 Lower plenum 26 Air supply shaft 28 Upper plenum 30 Exhaust shaft 32 Outside air inlet 34 Air outlet 36 Storage tube 38 Transfer room 40 Ceiling slag 42 Vitrified body 50 Concrete side wall 52 Inlet shielding plate 53 Exit shield plate 54 Side wall flow path forming plate 56 Side wall flow path 58 Rib 60 Ceiling flow path forming plate 62 Ceiling flow path 64 Air flow restrictor 70 Concrete proximal side wall 72 Concrete distal side wall

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Toshio Funakoshi 2-1-1 Shinhama, Arai-machi, Takasago City, Hyogo Prefecture Inside the Takasago Research Laboratory, Mitsubishi Heavy Industries, Ltd. 1-1 1-1, Mitsubishi Heavy Industries, Ltd., Kobe Shipyard

Claims (5)

[Claims] (1) four sides are surrounded by concrete side walls;
A plurality of storage pipes are juxtaposed in a cell chamber whose upper part is partitioned by a concrete ceiling slag, and this cell chamber communicates with an outside air introduction passage having an outside air inlet and is located below the plurality of storage pipes. And, having an upper plenum that communicates with a cooling air discharge passage provided with an air outlet and is located below the ceiling slag, the concrete side wall is provided with a side wall channel forming plate facing the inner surface of the concrete side wall,
A side wall channel for cooling the concrete side wall is formed between the concrete side wall and the side wall channel forming plate, and natural convection in the cell chamber generated by heat generated by the radioactive waste stored in each storage tube. In the radioactive waste storage facility that cools the storage pipe and the concrete side wall containing the radioactive waste by ventilation, the ceiling slag is provided with a ceiling channel forming plate facing the ceiling slag inner surface, and the ceiling slag inner surface is provided. A ceiling flow path communicating with the side wall flow path is formed between the ceiling flow path forming plate and the side wall flow path, and a partition extending from the lower plenum toward the upper plenum is provided in the side wall flow path. Facility 2. The four sides are surrounded by concrete side walls,
A plurality of storage pipes are juxtaposed in a cell chamber whose upper part is partitioned by a concrete ceiling slag, and this cell chamber communicates with an outside air introduction passage having an outside air inlet and is located below the plurality of storage pipes. And, having an upper plenum that communicates with a cooling air discharge passage provided with an air outlet and is located below the ceiling slag, the concrete side wall is provided with a side wall channel forming plate facing the inner surface of the concrete side wall,
A side wall channel for cooling the concrete side wall is formed between the concrete side wall and the side wall channel forming plate, and natural convection in the cell chamber generated by heat generated by the radioactive waste stored in each storage tube. In the radioactive waste storage facility that cools the storage pipe containing radioactive waste and the concrete side wall by ventilation, the cooling air discharge passage side formed between the concrete side wall and the side wall channel forming plate. A storage facility characterized in that an air flow restrictor is provided in the side wall flow path. 3. The storage facility according to claim 2, wherein said air flow restricting means comprises a perforated plate arranged so as to intersect the flow of cooling air in said side wall flow path. 4. The storage facility according to claim 2, wherein said air flow restricting means comprises a gap adjusting plate arranged along the flow of cooling air in said side wall flow path. 5. A plurality of storage tubes are juxtaposed in a cell room surrounded on all sides by a concrete side wall and an upper portion is partitioned by a concrete ceiling slag.
A lower plenum located below the plurality of storage tubes and leading to an outside air introduction passage having an outside air inlet; and an upper plenum located below the ceiling slag and leading to a cooling air discharge passage having an air outlet. This cooling air discharge passage
A cooling air discharge passage having a concrete proximal sidewall extending upwardly from the ceiling slag and located proximally of the cell chamber, and a concrete distal sidewall extending upwardly and located distally of the cell chamber. Has a plurality of shielding plates which protrude inward from the inner wall of each of the concrete proximal and distal side walls, alternately facing upward, and is generated by heat generated by radioactive waste contained in each storage tube. Cooling the storage pipe containing the radioactive waste and the concrete around the cell chamber by natural ventilation by convection in the cell chamber,
A radioactive waste storage facility wherein cooled air from an upper plenum is deflected upwardly by said inner wall of a concrete distal sidewall in said cooling air discharge passage toward an air outlet; A storage facility, wherein a shielding plate at a position is provided on an inner wall of the concrete proximal side wall.