JP2014025922A - Radioactive substance container, radioactive substance storage facility and its constructing method, and radioactive substance storage structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radioactive substance container excellent in radiation shielding performance and radioactive substance sealing performance and facilitating installation and relocation thereof, a radioactive substance storage facility and its constructing method, and a radioactive substance storage structure.SOLUTION: A radioactive substance container 10 having an internal space 12 for containing a radioactive substance and formed of a hollow steel pipe 14 to be embedded in the ground comprises: steel materials for blocking the end portions 14a and 14b of the hollow steel pipe 14; and a radiation shielding material 18 for covering the internal surface 14c of the hollow steel pipe 14. A constructing method of a radioactive substance storage facility having the radioactive substance container 10 embedded in the ground includes containing the radioactive substance in the internal space 12 before and after installing the radioactive substance container 10 in the ground.

Description

  The present invention relates to a radioactive substance storage container for storing waste such as concrete and debris contaminated with radioactive substances, rubble incineration ash, earth and sand, and a radioactive substance storage facility using the radioactive substance storage container and its The present invention relates to a construction method and a radioactive substance storage structure.

  When a very large earthquake such as the Great East Japan Earthquake occurs, nuclear power plants are damaged, radioactive materials are released in large quantities, and buildings and earth and sand are radioactively contaminated in many areas. In addition, radioactive waste is generated from nuclear facilities even during normal times. Such a substance that emits radiation has a great influence on human life unless it is properly treated.

  In particular, the diffusion of radioactive materials due to accidents at nuclear power plants caused by the Great East Japan Earthquake has become widespread, and its treatment is a problem. If left as it is, radiation will be emitted over a long period of time, and an appropriate treatment method is required.

  As a technique for sealing a substance contaminated with a radioactive substance, for example, methods as disclosed in Patent Documents 1 to 3 have been proposed.

  Patent document 1 makes the support pile of the building used as a nuclear facility hollow, and fills and encloses the activated concrete in the hollow pile as an intermediate material, and stores the activated concrete using the hollow pile as a storage container. Is. According to this patent document 1, it is possible to store a large amount of activated concrete safely and for a long time without requiring a special storage space, and the activated concrete can be reused as an intermediate material for hollow piles. It is used and is extremely reasonable and effective.

  Patent Document 2 is a steel pipe concrete pile as a foundation pile of a structure, in which a concrete pipe as waste is filled into a steel pipe provided to reach a support layer, and mortar is pressed into a hardened mortar. The concrete glass is enclosed in the whole steel pipe in a state where the concrete glass is embedded.

  In this patent document 2, it is effective means which enables the effective utilization of the concrete glass as industrial waste, and by extension, the activated concrete glass as very low level radioactive waste. And it is supposed that the concrete pile which is a waste can be used effectively as an intermediate material, and a structurally excellent foundation pile will be realized.

  In Patent Document 3, a tip shaft portion having a tip wing is attached to a lower end of an upper shaft portion so as to be detachable via a detachment mechanism, and is rotated and penetrated into the ground to reach a predetermined depth. Of the support body provided in the hole formed by pulling up the upper shaft portion on the upper portion of the tip shaft portion, which is separated from the portion and lifted only the upper shaft portion and left as a leading tip support body at the support ground position. The lower end is joined and the preceding tip support body and the support body are integrally formed as a foundation.

  In this Patent Document 3, the tip shaft portion is used as a canister for burying (can container), and in this canister, waste that can be disposed of in the target ground, for example, solid metal waste that has been solidified, insolubilized or reduced. It is said that canisters can be buried underground by containing organochlorine compounds, low-level radioactive waste, etc., buried to a predetermined depth in the ground, and refilling vacancies after lifting the upper shaft. .

  On the other hand, a screw-in type steel pipe pile is known in which a plurality of inclined steel plates (propulsion blades) are attached to the tip of a steel pipe (see, for example, Patent Document 4). The steel plate is provided with a screwing function for propelling the steel pipe pile into the ground. By screwing the steel pipe pile, it can be buried in the ground without waste.

JP 2000-131696 A JP 2000-204547 A JP 2002-363981 A JP-A-9-324419

  By the way, in said patent document 1, the steel pipe and PHC pile are used as a hollow pile, The front-end | tip is obstruct | occluded with the sealing concrete which added the water-stopping agent, and perfect water-tightness is ensured. However, in the ground subjected to pressure, water may flow into the pipe at the time of construction, making it difficult to place concrete, which may prevent placement of high-quality concrete. In addition, since radioactive waste is generally stored for a long period of time, there is a risk of radioactive material leaking into the ground when the sealed concrete portion at the tip deteriorates over time. Moreover, since waste is put directly into the hollow pile, the radiation passes through the pile and is discharged into the ground. For example, the radiation shielding effect is small.

  Moreover, in said patent document 2, although the water-stopping concrete is cast in the front-end | tip part in a steel pipe and the front-end | tip part is sealed, like the case of patent document 1, the problem that placement is difficult, There is a risk that radioactive materials may leak due to deterioration. Moreover, in order to use the concrete glass which is a waste as an intermediate material, it is necessary to pulverize the concrete glass to a predetermined particle size (about 5 to 10 cm) in advance, which takes time and cost. Moreover, only the concrete glass can be used from the necessity to ensure the intensity | strength as an inside material, and earth and sand, wood chips, etc. cannot be mixed.

  In addition, in said patent document 1 and 2, although it is suggested that the radioactive substance currently stored is taken out from the pile and moved to another place, it is difficult in practice, and once buried in the ground It can be said that it can only be stored permanently in the place.

  Moreover, in said patent document 3, although the front-end | tip axis | shaft part is utilized as a canister for embedding, the capacity | capacitance becomes what was restrict | limited small. Also, once buried in the ground, it is difficult to take it out to the ground.

  The present invention has been made in view of the above, and has a radioactive shielding container, a radioactive substance storage facility, a construction method thereof, and a radioactive substance that have excellent radiation shielding performance and radioactive substance sealing performance, and are easy to install and relocate. The object is to provide a material storage structure.

  In order to solve the above-described problems and achieve the object, (1) a radioactive substance storage container according to the present invention includes a hollow steel pipe that has an internal space for storing a radioactive substance and can be embedded in the ground. It is a radioactive substance storage container, Comprising: The steel material which obstruct | occludes the front-end | tip part of the said hollow steel pipe, and the radiation shielding material which coat | covers the inner surface of the said hollow steel pipe, It is characterized by the above-mentioned.

  (2) In addition, another radioactive substance storage container according to the present invention is characterized in that, in the above-described (1), a propulsion blade is provided at or near the tip of the hollow steel pipe.

  (3) Further, in the radioactive substance storage container according to the present invention, in the above (1) or (2), the radiation shielding material is sandwiched between the inner surface of the hollow steel tube and the steel material provided in the hollow steel tube. It is characterized by that.

  (4) Further, in the radioactive substance storage container according to the present invention, in (3) described above, a tube with a closed end is inserted into the hollow steel tube to form a double tube structure. The radiation shielding material is filled between the tubes.

  (5) Moreover, the other radioactive substance storage container which concerns on this invention is the crushed stone, earth and sand, slag, iron ore, iron powder in any one of (1)-(4) mentioned above. It consists of at least one of cement-based solidified material, cement-based solidified material with slag, lead, and lead compound.

  (6) The radioactive substance storage facility according to the present invention is characterized in that the radioactive substance storage container according to any one of (1) to (5) described above is embedded in the ground.

  (7) Moreover, the construction method of the radioactive substance storage facility which concerns on this invention is the radioactive substance storage which embeds the radioactive substance storage container as described in any one of (1)-(5) mentioned above in the ground. A method for constructing a facility, wherein the radioactive substance is stored in the internal space before or after the radioactive substance storage container is installed on the ground.

  (8) Moreover, the radioactive substance storage structure which concerns on this invention is a high level stored in the internal space of the radioactive substance storage container as described in any one of (1)-(5) mentioned above, and the said hollow steel pipe. And a low level radioactive material disposed around the high level radioactive material.

  According to the radioactive substance storage container according to the present invention, the radioactive substance storage container includes a hollow steel pipe having an internal space for storing the radioactive substance and embeddable in the ground. Since it comprises a steel material that closes and a radiation shielding material that covers the inner surface of the hollow steel pipe, radiation such as gamma rays emitted from the stored radioactive material is shielded by the radiation shielding material, and emission to the outside of the hollow steel pipe is suppressed. . Thus, since it is excellent in the radiation shielding performance and the sealing performance of the radioactive substance, when the radioactive substance storage container is embedded in the ground, the surrounding ground is not radioactively contaminated.

1A and 1B are diagrams showing a radioactive substance storage container according to Embodiment 1 of the present invention, in which FIG. 1A is a longitudinal sectional view and FIG. 1B is a transverse sectional view. FIG. 2 is a diagram showing a construction method of the radioactive substance storage facility according to the first embodiment of the present invention. FIGS. 3-1 is a figure which shows the radioactive substance storage container of Embodiment 2 of this invention, (a) is a principal part perspective view, (b) is a bottom view. 3-2 is a figure which shows the other example of the radioactive substance storage container of Embodiment 2 of this invention, (a) is a principal part perspective view, (b) is a bottom view. FIG. 3C is a schematic bottom view and a side view showing an example of a variation of the propulsion blade shown in FIG. 3-2. FIG. 4 is a diagram showing a construction method of the radioactive substance storage facility according to the second embodiment of the present invention. FIG. 5 is a view showing a radioactive substance storage container according to Embodiment 4 of the present invention, in which (a) is a longitudinal sectional view and (b) is a transverse sectional view. 6A and 6B are diagrams showing a radioactive substance storage container according to Embodiment 5 of the present invention, in which FIG. 6A is a longitudinal sectional view, and FIG. 6B is a transverse sectional view. FIG. 7 is a diagram showing a construction method of the radioactive substance storage facility according to Embodiment 6-1 of the present invention. FIG. 8 is a diagram showing a construction method of the radioactive substance storage facility according to Embodiment 6-2 of the present invention. FIG. 9 is a diagram showing a radioactive substance storage structure according to the seventh embodiment of the present invention. FIG. 10 is a model diagram of the radioactive substance storage container used for verification of the gamma ray shielding effect according to the present invention.

  Embodiments (Embodiments 1 to 7) of a radioactive substance storage container, a radioactive substance storage facility construction method, and a radioactive substance storage structure according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

[Embodiment 1]
As shown in FIG. 1, the radioactive substance storage container 10 according to the first embodiment of the present invention includes wastes such as concrete, rubble, rubble incineration ash, earth and sand contaminated with radioactive substances (hereinafter referred to as radioactive substances). A plate-shaped canopy 16a and a bottom lid 16b (steel material), each of which has a hollow steel tube 14 having an internal space 12 for storing, and closes the upper and lower end portions 14a and 14b (tip portions) of the hollow steel tube 14. ) And a radiation shielding material 18 that covers the inner surface 14c of the hollow steel pipe 14.

  As the hollow steel pipe 14, a single pipe for a steel pipe pile embedded in the ground can be used as a support pile of a building. For example, a single pipe suitable for JIS A 5525 (steel pipe pile) can be used.

  The bottom cover 16b is a steel material fixed to the lower end part 14b by welding. Here, if the bottom cover 16b is made of concrete, there is a possibility that radioactive material thrown into the hollow steel pipe 14 leaks to the outside due to cracks or the like. Therefore, in the present invention, the bottom cover 16b is made of a steel material that can be surely sealed. We are trying to weld. The upper surface of the bottom cover 16 b may be covered with the radiation shielding material 18. The lower surface of the canopy 16a is covered with a radiation shielding material (not shown) made of the same concrete as the radiation shielding material 18, and is fixed to the upper end portion 14a by welding a steel material portion.

  Radiation emitted by radioactive materials includes alpha rays, beta rays, and gamma rays. Although alpha rays and beta rays can be shielded with paper or aluminum plate, gamma rays have very high penetrating power and are dense with concrete and lead. It has the property of decaying when there is a substance. Therefore, in the present invention, the radioactive substance is not stored directly in the hollow steel pipe 14 but is stored via the radiation shielding material 18 made of a substance having a high density such as concrete or lead covering the inner surface of the hollow steel pipe 14. To do. By doing so, radiation such as gamma rays emitted from the radioactive substance stored inside is shielded by the radiation shielding material 18, and emission to the outside of the hollow steel pipe 14 is suppressed.

  Thus, since this invention is excellent in the radiation shielding performance and the sealing performance of a radioactive substance, when the radioactive substance storage container 10 is embed | buried in the ground, a surrounding ground is not radioactively contaminated.

  Here, the radiation shielding material 18 of the present invention may be made of any material as long as it has a high density such as concrete or lead and can effectively shield gamma rays. For example, crushed stone, earth and sand, slag, etc. , Iron ore, iron powder, cement-based solidified material such as concrete and mortar, slag-containing cement-based solidified material, lead, lead compound, barium, and barium compound. However, in this Embodiment 1, the case where a cement-type solidification material or a slag containing cement-type solidification material is used is demonstrated.

  In this case, not only ordinary concrete and ordinary mortar, but also concrete and mortar using steel slag as an aggregate can be used. In particular, since steelmaking slag contains a large amount of iron components, it contributes to an increase in specific gravity and is effective in improving shielding performance. In addition, concrete or mortar using iron ore as an aggregate may be used.

  In addition, when lining a cement-type solidification material with a centrifugal force, it is given before installing in the ground. When the cement-based solidified material is placed on the inner surface of the steel pipe 14 using a mold or the like, it may be before or after being installed in the ground. Further, the tube thickness of the hollow steel tube 14 and the coating thickness of the radiation shielding material 18 may be set as appropriate based on the relationship between the thickness and the radiation shielding performance obtained in advance through experiments or the like.

  Next, a method for constructing the radioactive substance storage facility of the present invention in which the radioactive substance storage container 10 is buried in the ground will be described with reference to FIG.

  As shown in FIG. 2A, the radioactive substance storage container 10 in which the inner surface of the hollow steel pipe 14 is covered with the radiation shielding material 18 is embedded in the ground G. Here, the lower end portion 14b of the hollow steel pipe 14 is sealed by welding the bottom lid 16b, and the upper end portion 14a not yet provided with the canopy 16a is open. Subsequently, as shown in FIG. 2B, after the radioactive substance 1 is introduced into the internal space 12, the canopy 16a is fixed to the upper end portion 14a by welding or the like and completely shielded.

  Thus, the radioactive substance storage facility can be built in the ground by storing the radioactive substance 1 in the internal space 12 after installing the radioactive substance storage container 10 on the ground. On the contrary, the radioactive substance 1 may be introduced into the hollow steel pipe 14 in advance, and the radioactive substance storage container 10 may be embedded in the ground after the upper end portion 14a is sealed with the canopy 16a. . In the present embodiment, the case where one radioactive substance storage container 10 is embedded in the ground is shown. However, a radioactive substance storage facility may be constructed by embedding a plurality of radioactive substance storage containers 10 in the vicinity. Absent.

  Here, as a method for embedding the radioactive substance storage container 10 in the ground, there are a batting method, a pre-boring method, a rotating method, and the like, but it is preferable to select appropriately according to the ground conditions and the like.

  In this way, it is better to bury the radioactive substance storage container in the ground and construct the radioactive substance storage facility, compared to the case where the radioactive substance storage container is placed on the ground, and to improve the earthquake resistance. It is relatively safe because there is no risk of radiation emission.

  Moreover, since the hollow steel pipe 14 is not used as a support pile for supporting a building, it is not always necessary to install it in a support layer having a large N value, and it can be stopped by an intermediate soft layer, so that construction is easy. . The length of the hollow steel pipe 14 is preferably set as appropriate in consideration of the condition of the ground to be embedded and the ease of transportation and movement before and after the embedding. For example, a length of about 3 m to 50 m should be used. Can do.

  However, when the hollow steel pipe 14 is formed by adding a plurality of steel pipes, the steel pipe part can be connected by welding, but the inner concrete lining part (radiation shielding material 18) has a seam and becomes discontinuous. After that, it is necessary to devise such as placing concrete over the entire inner surface of the hollow steel pipe 14. Therefore, it is preferable to use the hollow steel pipe 14 as a seamless single pipe such as a welded part from the viewpoint of ensuring the sealing performance.

  Moreover, since it is one of the advantages that the radioactive substance storage container of this invention can be comprised so that conveyance is possible, it is desirable to set the length of the hollow steel pipe 14 to the length which can be easily conveyed with a trailer etc. In consideration of convenience such as land transportation by a trailer or the like, the single tube length of the hollow steel tube is preferably about 13 to 20 m, but other single tube lengths may of course be used. In addition, about the hollow steel pipe of length 15m or less, it pulls out from the ground and is easy to carry and move.

[Embodiment 2]
As illustrated in FIG. 3A, the radioactive substance storage container 20 according to the second embodiment of the present invention includes a winged steel pipe 22 (hollow steel pipe) having an internal space 12 for storing the radioactive substance. The radiation shielding material 18 which coat | covers the inner surface 22c of the steel pipe 22 is provided. A propulsion blade 24 for ground penetration is provided at the lower end portion 22b (tip portion or its vicinity) of the steel tube 22 with wings. The propulsion blade 24 is made of a semicircular or fan-shaped steel material divided into two in the circumferential direction, and is attached to be inclined with respect to the extending direction of the bladed steel pipe 22. In addition, although the canopy similar to said Embodiment 1 is provided in the upper end part of the winged steel pipe 22, illustration is abbreviate | omitted in FIG. 3-1. Further, since the radiation shielding material 18 is the same as that of the first embodiment, detailed description thereof is omitted.

  The winged steel pipe 22 can be constructed without using the propulsion wing 24 in the manner of a wood screw. The blade diameter can be about 1.5 to 3 times the steel pipe diameter. If the blade diameter is small, the effect of obtaining a propulsive force is small, and if the blade diameter is large, the torque required for construction increases. The double wings have a good balance between torque and thrust.

  Unlike the general rotary penetration steel pipe pile, this winged steel pipe 22 does not support the structure as a foundation pile, so it is not necessary to increase the plate thickness of the propulsion blade 24, and the propulsive force at the time of burial construction can be obtained. The thin plate thickness required for this is sufficient. When the propulsion blade 24 is attached so as to close the lower end portion 22b as shown in FIG. 3-1, the same role as the bottom cover 16b (see FIG. 1) similar to that of the first embodiment can be achieved. it can.

  Further, the propulsion blade 24 may be divided into a plurality of pieces in the circumferential direction, or may be arranged in a plurality of stages in the extending direction of the steel pipe 22. Moreover, you may arrange | position continuously helically or may arrange | position discontinuously like a 1 step | paragraph blade. The arrangement of the propulsion blades 24 is preferably selected as appropriate in consideration of ground conditions and workability. Further, as for the shape of the blade itself, a flat plate blade, a bent spiral blade, or the like can be used.

  In the present embodiment, as the propulsion blade, a propulsion blade that is attached so as to close the lower end portion 22b of the bladed steel pipe 22 and also serves as the bottom lid 16b (see FIG. 1) (closed end type) is used. However, the propulsion blade of the present invention is not limited to this. For example, as shown in FIG. 3-2, the propulsion blade has a configuration in which the lower end portion 54b of the winged steel pipe 54 is attached so as not to be closed (open). End type) may be used. However, it is necessary to install a bottom cover 54c inside the steel pipe 54 above the lower end portion 54b in order to prevent earth and sand from entering from the opened lower end portion 54b when rotating and penetrating into the ground. The bottom lid 54c is installed within a range from the tip to 5D (D indicates the outer diameter of the steel pipe 54). If the bottom cover installation position exceeds 5D, the internal space volume of the steel pipe decreases, so a range up to 5D is desirable. In the case of this embodiment, the range from the tip to 5D is regarded as the tip.

  Here, the winged steel pipe 54 has a substantially spiral propulsion blade 56 formed by two fan-shaped flat plates (steel plates) 56a and 56b having a total inner angle of 270 ° to 450 ° at the tip. It is configured as a screwed pile that is attached and penetrates and buried in the ground by applying a rotational force to the steel pipe 54. Here, when the fan-shaped flat plate 56a that first penetrates into the ground is referred to as the lower wing 56a, and the other fan-shaped flat plate 56b is referred to as the upper wing 56b, The connection position 56c with the upper wing 56b is outside the steel pipe 54, and the inclination angle of the lower wing 56a and the inclination angle of the upper wing 56b with respect to the pipe axis direction of the steel pipe 54 are substantially equal.

  In addition, as an open end type propulsion blade, one having a shape other than the above is applicable. FIG. 3C is a schematic bottom view and a side view showing an example of a variation of the propulsion blade shown in FIG. 3-2. 3A corresponds to that of the propulsion blade 56 described above. A winged steel pipe 54 shown in FIG. 3-3 (b) has a substantially spiral propulsion blade 58 attached thereto. A winged steel pipe 54 shown in FIG. 3-3 (c) is one in which fan-shaped flat plates 60a and 60b are attached so as to intersect at the center of the steel pipe.

  Next, a method for constructing the radioactive substance storage facility of the present invention in which the radioactive substance storage container 20 is buried in the ground will be described with reference to FIG.

  As shown in FIGS. 4A and 4B, a rotational force is applied to the winged steel pipe 22 whose inner surface is covered with the radiation shielding material 18 and screwed into the ground G. Here, the upper end 22a where the canopy 16a is not yet provided is open. Subsequently, as shown in FIG. 4C, after the radioactive substance 1 is introduced into the internal space 12, the canopy 16a is fixed to the upper end portion 22a by welding or the like and completely shielded.

  Thus, the radioactive substance storage facility can be built in the ground by storing the radioactive substance 1 in the internal space 12 after installing the radioactive substance storage container 20 on the ground. On the other hand, the radioactive substance 1 may be introduced into the steel pipe 22 in advance and the upper end portion may be sealed with the canopy 16a, and then the radioactive substance storage container 20 may be embedded in the ground. In the present embodiment, the case where one radioactive substance storage container 20 is embedded in the ground is shown. However, a radioactive substance storage facility may be constructed by burying a plurality of radioactive substance storage containers 20 close to each other. Absent.

  In particular, according to the present embodiment, the winged steel pipe 22 having the propulsion blades 24 attached to the lower end portion 22b can be rotated and screwed into the ground easily without soil. Further, the winged steel pipe 22 once buried in the ground is easily pulled out by rotating in the reverse direction. For this reason, if it is desired to move the stored radioactive substance 1 to another location, the radioactive substance 1 can be transferred as it is stored in the winged steel pipe 22 without being taken out of the internal space 12. The time and cost of taking out can be saved. And if rotation penetration construction is performed again at the transfer destination, it can be re-installed in the ground.

[Embodiment 3]
The radioactive substance storage container according to the third embodiment of the present invention comprises a hollow steel pipe 14 having an internal space 12 for storing radioactive substances, as in the first embodiment (see FIG. 1). A plate-shaped canopy 16a and bottom cover 16b (steel material) that respectively close upper and lower end portions 14a and 14b (tip portions) of the steel pipe 14 and a radiation shielding material 18 that covers the inner surface 14c of the hollow steel pipe 14 are provided.

  Here, in the present embodiment, lead or a lead compound is used as the radiation shielding material 18. Since lead or a lead compound is an inexpensive material having a relatively large specific gravity, the coating thickness can be reduced and a capacity for storing radioactive substances can be obtained.

[Embodiment 4]
As shown in FIG. 5, the radioactive substance storage container 40 of Embodiment 4 of this invention consists of the hollow steel pipe 14 which has the internal space 12 for storing a radioactive substance, The upper-lower end part 14a of the hollow steel pipe 14, A plate-shaped canopy 16a and a bottom cover 16b (steel material) that respectively close the front end 14b and a radiation shielding material 18 that covers the inner surface 14c of the hollow steel tube 14 are provided.

  Here, the radiation shielding material 18 is sandwiched between the inner surface 14 c of the hollow steel pipe 14 and the steel material 42 provided in the hollow steel pipe 14. As the steel material 42, a steel pipe having both ends opened can be used. As for the radiation shielding material 18, as in the first or third embodiment, crushed stone, earth and sand, slag, iron ore, iron powder, cement-based solidified material, slag-containing cement-based solidified material, lead, lead compound, etc. Can be used.

[Embodiment 5]
As shown in FIG. 6, the radioactive substance storage container 50 according to the fifth embodiment of the present invention includes a steel pipe 52 (tube) whose tip is closed in the internal space 12 of the hollow steel pipe 14 in the configuration of the first embodiment. A double tube structure is inserted, and the radiation shielding material 18 is filled between the hollow steel tube 14 and the steel tube 52. By doing so, the radiation shielding material 18 is sandwiched between the inner surface 14 c of the hollow steel pipe 14 and the steel pipe 52. Since the steel pipe 52 is also a substitute for a mold for filling the radiation shielding material 18, a material other than a steel pipe, such as a polyethylene pipe, can be substituted.

  As the radiation shielding material 18, crushed stone, earth and sand, slag, iron ore, iron powder, cement-based solidified material, cement-based solidified material with slag, lead, lead compounds, and the like are used as in the fourth embodiment. However, cement-based solidified materials and slag-containing cement-based solidified materials are more suitable from the viewpoint of workability.

  As a method for constructing a radioactive substance storage facility using the radioactive substance storage container 50, after the hollow steel pipe 14 having a sandwich structure is installed on the ground, the radioactive substance 1 may be introduced into the internal space 12, or the radioactive substance may be radioactive in advance. The substance 1 may be put into the internal space 12 and the canopy 16a may be used before being embedded in the ground.

[Embodiment 6-1]
The method for constructing the radioactive substance storage facility according to Embodiment 6-1 of the present invention uses the radioactive substance storage container 50 according to Embodiment 5 described above. As shown in FIG. 7A, after the hollow steel pipe 14 is first embedded in the ground G, a steel pipe 52 whose tip is closed is inserted into the internal space 12 of the hollow steel pipe 14 to form a double pipe structure. Then, as shown in FIG.7 (b), between the hollow steel pipe 14 and the steel pipe 52, crushed stone, earth and sand, slag, iron ore, iron powder, cement type solidification materials, such as concrete and mortar, or slag containing cement type A solidifying material (radiation shielding material 18) is filled. By doing in this way, the steel pipe 52 can be used as a formwork for the solidified material 18. After the filled solidified material 18 is cured, as shown in FIG. 7C, the radioactive substance 1 is introduced and the upper end portion is sealed with the canopy 16a.

[Embodiment 6-2]
The construction method of the radioactive substance storage facility of Embodiment 6-2 of this invention is a modification of said Embodiment 6-1. As shown in FIG. 8 (a), the winged steel pipe 22 is first screwed into the ground G and buried, and then the steel pipe 52 whose tip is closed is inserted into the internal space 12 of the winged steel pipe 22 to thereby double pipe. Structure. Subsequently, as shown in FIG. 8B, a cement-based solidifying material such as concrete or mortar or a slag-containing cement-based solidifying material (radiation shielding material 18) is filled between the winged steel pipe 22 and the steel pipe 52. . By doing in this way, the steel pipe 52 can be substituted for the formwork of the solidification material 18 similarly to said Embodiment 6-1. After the filled solidified material 18 is cured, as shown in FIG. 8C, the radioactive substance 1 is introduced and the upper end portion is sealed with the canopy 16a.

  By carrying out like said Embodiment 6-1 or 6-2, a radioactive substance storage facility can be built in the ground. In this embodiment, the case where one radioactive substance storage container is embedded in the ground is shown. However, a radioactive substance storage facility may be constructed by burying a plurality of radioactive substance storage containers close to each other.

  In said embodiment, as a diameter dimension of the hollow steel pipe 14 or the winged steel pipe 22, a thing with a diameter of about 200-2500 mm can be used, and a thing with a diameter of about 1600 mm is more preferable. The larger the diameter of the steel pipe, the more the storage volume can be gained, but there is a problem that the construction difficulty level becomes higher. Therefore, it is desirable to set appropriately considering the ground conditions and the like. Moreover, as a combination of the diameters of the steel pipes 14 and 22 and the internal steel pipe 52 for forming a double pipe structure, for example, when placing on soft ground, the hollow steel pipe has a steel pipe diameter of about 1600 mm and a plate thickness of about 16 mm. The inner steel pipe includes a combination of a steel pipe diameter of 1400 mm and a plate thickness of about 14 mm. When the ground is hard, the thickness of the outer hollow steel pipe is preferably 1% or more, more preferably 1.3% or more, so that the steel pipe is not broken by rotational torque. There is no plate thickness limitation on the inner steel pipe, but generally it may be about 1% of the diameter of the steel pipe. The plate | board thickness of a steel pipe can be suitably changed according to the level of shielding performance.

[Embodiment 7]
The radioactive substance storage structure according to the seventh embodiment of the present invention has a structure similar to that of the above-described embodiment 6-2. For example, as shown in FIG. 9 (e), the hollow steel pipe 14 of the radioactive substance storage container, The high-level radioactive substance A1 stored in the internal space 12 of the hollow steel pipe 14 and the low-level radioactive substance A2 disposed around the outside so as to surround the high-level radioactive substance A1.

  An example of the construction method of this radioactive substance storage structure will be described with reference to FIG. As shown in FIG. 9 (a), first, after a winged steel pipe made of a hollow steel pipe 14 provided with propulsion blades 24 is screwed into the ground G in advance, as shown in FIG. 9 (b), A steel pipe 52 whose tip is closed is inserted into the internal space 12 of the hollow steel pipe 14 to form a double pipe structure. Here, the hollow steel pipe 14 and the steel pipe 52 are preferably arranged coaxially. Subsequently, as shown in FIG. 9 (c), the hollow steel pipe 14 and the steel pipe 52 are filled with cement-based solidifying material such as concrete or mortar, or slag-containing cement-based solidifying material (radiation shielding material 18). By doing in this way, the steel pipe 52 can be used as a formwork of the solidification material 18 similarly to said Embodiment 6-2. After the filled solidified material 18 is cured, as shown in FIG. 9 (d), a steel pipe 68 with a closed end is inserted into the internal space of the steel pipe 52 to form a triple pipe structure. Here, the steel pipe 68 and the steel pipe 52 are preferably arranged coaxially. Finally, as shown in FIG. 9 (e), a high level radioactive material A1 is introduced into the steel pipe 68, and a low level radioactive material A2 is introduced into the gap between the steel pipe 52 and the steel pipe 68 on the outer side. Then, the upper end is sealed with a canopy (not shown).

  In this way, if a substance that emits a lot of radiation (high-level radioactive substance A1) is arranged on the inside and a relatively low-level radioactive substance (low-level radioactive substance A2) is installed on the outside, the inside substance A1 Therefore, the radioactive substance storage structure of the present embodiment is effective for efficiently shielding the radiation.

  In the present embodiment, the steel pipe 68 is described as an example of the triple pipe, but the present invention is not limited to this, and any material and form may be used as long as the structure can contain a radioactive substance. Good. For example, a polyethylene pipe may be used instead of the steel pipe 68, or a bag shape or a container shape may be used. Further, the present invention is not limited to the triple tube, and may be composed of more multiple tubes. And you may arrange | position so that a low level radioactive material may be located gradually as it goes to an outer side pipe | tube from an innermost pipe | tube.

[Verification of gamma ray shielding effect according to the present invention]
Next, verification of the gamma ray (γ ray) shielding effect according to the present invention will be described.
First, as basic experiment, steel plate having a thickness of 9 mm, plain concrete blocks density 2.56 g / cm ^{3, 60} for converter slag containing concrete blocks density ^{2.59g / cm 3 Co (1.733MeV,} 1.333MeV) The transmittance of gamma rays from was measured. And based on the following reference 1, the concrete equivalent thickness of the shielding body was determined using the transmittance at ⁶⁰ Co, and the linear attenuation coefficient for gamma rays from ¹³⁷ Cs with energy of 0.662 MeV was converted from the thickness. The steel sheet thickness and concrete thickness (1/10 attenuation thickness) at which the transmittance was 1/10 were obtained by calculation. The results are shown in Table 1. In Table 1, the thickness (1/2 attenuation thickness) at which the transmittance is ½ is also shown.

  [Reference 1] Japan Atomic Energy Agency, “Constant calculation for shielding against photon, neutron, and beta bremsstrahlung for effective dose evaluation”, P.65, P.84, January 2001

  From this table, it can be seen that in order to obtain a transmittance of 1/10, a steel plate needs to have a thickness of about 4.5 cm, ordinary concrete needs a thickness of about 13 cm, and converter slag-containing concrete needs a thickness of about 11 cm.

  Based on the results of this basic experiment, a single tube model of the side sectional view of FIG. 10A and a double tube model as shown in the side sectional view of FIG. Assumed. FIG. 10C is a perspective view of FIG. Further, in any model, it is assumed that the upper and lower end portions are completely shielded by the lids 16a and 16b and embedded in the ground G as shown in FIG. Here, as shown in FIG. 10 (a), the single pipe model is a system in which the inside of the steel pipe 62 is lined with the above-described converter slag-containing concrete 66, and the double pipe model is shown in FIG. 10 (b). As shown in (d) to (d), the above-described converter slag-containing concrete 66 is filled between the outer steel pipe 62 and the inner steel pipe 64, and in each case, the radioactive substance 1 is filled.

  In the single pipe model of FIG. 10A, the thickness of the converter slag-containing concrete 66 and the shielding effect only by the outer steel pipe 62 may be considered. In addition, the bottom cover and canopy which are not shown in figure can use the steel plate of 60 mm or more with sufficient shielding effect, for example. Table 2 shows the result of trial calculation of the shielding effect in the single pipe model.

As shown in Table 2, ¹³⁷ Cs gamma rays from the radioactive waste 1 filled inside the pipe are attenuated by the thickness of the steel pipe and the thickness of the lined converter slag-containing concrete, but the thickness of the steel pipe and the lining thickness are reduced. If it is insufficient, a sufficient attenuation rate cannot be obtained. For example, when considering attenuation to 1/20 (= 0.05) of the initial strength as an environmentally safe index, the trial calculation cases of numbers 2-3, 2-4, and 2-9 are the thicknesses of the steel pipes. It can also be seen that the attenuation rate does not reach 1/20 because the lining thickness is insufficient. A large-diameter steel pipe capable of storing a large amount of radioactive material requires a plate thickness of about 20 mm in order to ensure strength. Therefore, if the thickness d of the concrete containing the converter slag to be lined is about 100 mm, sufficient attenuation is possible.

Next, Table 3 shows a trial calculation result of the shielding effect in the double pipe model of FIG. This table is a trial calculation of the shielding effect against ¹³⁷ Cs gamma rays when considering the thickness of the steel plate thickness and the concrete containing the converter slag, assuming the typical blade pile size corresponding to the double pipe model. It is.

  As shown in Table 3, in most steel sheet sizes, the gamma ray transmittance of the radioactive material filled in the inner steel pipe is 1/2 depending on the thickness of the inner steel pipe, the thickness d of the concrete containing the converter slag and the thickness of the outer steel pipe. Since it can be attenuated to an attenuation factor of 20 (= 0.05) or less, safety can be ensured without any problem. In addition, the trial calculation cases of numbers 3-3, 3-4, 3-10, and 3-13 do not reach the attenuation factor of 1/20 because the thickness of the steel pipe and the lining thickness are insufficient. In addition, as a condition for realizing the attenuation factor of 1/20, it is only necessary to realize a construction in which a constant linear attenuation coefficient is obtained even if the gap between the inner steel pipe and the outer steel pipe is not filled with the converter slag-containing concrete.

  As described above, the radioactive substance storage container according to the present invention is a radioactive substance storage container comprising a hollow steel pipe having an internal space for storing a radioactive substance and embeddable in the ground, Since it has a steel material that closes the tip of the hollow steel pipe and a radiation shielding material that covers the inner surface of the hollow steel pipe, radiation such as gamma rays emitted from the stored radioactive material is shielded by the radiation shielding material, and the outside of the hollow steel pipe Release is suppressed. Thus, since it is excellent in the radiation shielding performance and the sealing performance of the radioactive substance, when the radioactive substance storage container is embedded in the ground, the surrounding ground is not radioactively contaminated.

  Moreover, when a propulsion blade is provided at or near the tip of the hollow steel pipe in addition to the above configuration, the hollow steel pipe can be easily embedded in the ground without any soil by rotating and screwing the hollow steel pipe. Moreover, the hollow steel pipe once buried in the ground is easily pulled out by rotating in the reverse direction. For this reason, when moving the stored radioactive substance to another place, it can be transferred as it is stored in the hollow steel pipe without being taken out from the inside.

  As described above, the radioactive substance storage container, the radioactive substance storage facility and the construction method thereof, and the radioactive substance storage structure according to the present invention include concrete, rubble, rubble incineration ash, earth and sand, etc. contaminated with radioactive substances. It is useful for storage and storage, and is particularly suitable for improving radiation shielding performance and radioactive material sealing performance.

10, 20, 40, 50 Radioactive substance storage container 12 Internal space 14 Hollow steel pipe 14a, 22a Upper end (tip)
14b, 22b, 54b Lower end (tip)
14c, 22c inner surface 16a canopy (steel material)
16b, 54c Bottom cover (steel)
18 Radiation shielding material or solidification material 22,54 Winged steel pipe (hollow steel pipe)
24, 56, 58 Propeller blade 42 Steel 52, 68 Steel pipe (pipe)
56a, 56b, 60a, 60b Fan-shaped flat plate (steel plate)
56c Connection position 1 Radioactive material G Ground

Claims (8)

A radioactive substance storage container comprising a hollow steel pipe having an internal space for storing radioactive substances and embeddable in the ground,
A radioactive substance storage container comprising: a steel material that closes a distal end portion of the hollow steel pipe; and a radiation shielding material that covers an inner surface of the hollow steel pipe.   The radioactive substance storage container according to claim 1, wherein a propulsion blade is provided at or near the tip of the hollow steel pipe.   The radioactive substance storage container according to claim 1 or 2, wherein the radiation shielding material is sandwiched between an inner surface of the hollow steel tube and a steel material provided in the hollow steel tube.   The radioactive material according to claim 3, wherein a tube having a closed end is inserted into the hollow steel tube to form a double tube structure, and the radiation shielding material is filled between the hollow steel tube and the tube. Substance containment vessel.   5. The radiation shielding material is made of at least one of crushed stone, earth and sand, slag, iron ore, iron powder, cement-based solidified material, cement-based solidified material with slag, lead, and lead compound. The radioactive substance storage container as described in any one of these.   The radioactive substance storage container as described in any one of Claims 1-5 is embed | buried in the ground, The radioactive substance storage facility characterized by the above-mentioned.   It is a construction method of the radioactive substance storage facility which embeds the radioactive substance storage container as described in any one of Claims 1-5 in the ground, Comprising: Before or after installing a radioactive substance storage container in the ground Is stored in the internal space. A method for constructing a radioactive substance storage facility.   The radioactive substance storage container according to any one of claims 1 to 5, a high level radioactive substance stored in an internal space of the hollow steel pipe, and a low level disposed around the high level radioactive substance A radioactive substance storage structure comprising:

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