JP6324139B2 - Radioactive material storage container, radioactive material storage and transport method - Google Patents

Description

  The present invention relates to a radioactive substance storage container for storing a radioactive substance therein, and a method for storing and transporting the radioactive substance.

  The spent fuel used in the nuclear power plant is temporarily stored in a spent fuel storage pool in the reactor container and cooled. Spent fuel cooled in the spent fuel storage pool is transported to a reprocessing facility.

  However, the spent fuel storage pool has a limited storage capacity, and thus spent fuel may be stored in a radioactive substance storage container (cask). Spent fuel may also be stored in a cask and transported to a reprocessing facility. In general, a cask has a container for storing spent fuel, and a primary lid and a secondary lid for sealing the container. In addition to a primary lid and a secondary lid, Patent Document 1 discloses a cask having a storage tertiary lid that contains a shielding material and shields radiation.

JP-A-11-287893

  By the way, recently, a cask that stores spent fuel is required to have soundness against severe accidents such as aircraft falling. In the event of a severe accident such as an aircraft falling, it is conceivable that flying objects collide with the cask. For this reason, it is desirable to provide the cask with impact resistance because it is necessary to ensure soundness against severe accidents such as aircraft dropping.

  It is an object of the present invention to provide a radioactive substance storage container and a radioactive substance storage and transportation method that improve impact resistance in order to ensure soundness against severe accidents such as aircraft falling.

  In order to solve the above-described problems and achieve the object, the radioactive substance storage container of the present invention is a cylindrical member having an opening at one end, and a trunk main body capable of containing the radioactive substance therein. A primary lid detachably attached to the opening; a secondary lid detachable outside the primary lid in the opening; and a secondary lid detachable outside the secondary lid in the opening And a tertiary lid that protects the lid from external impacts.

  According to this radioactive substance storage container, since the tertiary lid protects the secondary lid, the impact resistance of the radioactive substance storage container can be improved.

  In the radioactive substance storage container, the tertiary lid has a cover portion covering at least a part of a side surface of the trunk body on an outer peripheral portion thereof. According to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be further improved by the cover.

  In the radioactive substance storage container, it is preferable that a first space is provided between the secondary lid and the tertiary lid. The first space between the secondary lid and the tertiary lid can reduce the impact on the radioactive substance storage container. Therefore, according to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be further improved.

  In the radioactive substance storage container, it is preferable that a second space is provided between the cover portion and a side surface of the trunk body. The second space between the cover part and the side surface of the trunk body can reduce the impact on the radioactive substance storage container. Therefore, according to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be further improved.

  In the radioactive substance storage container, a transport tertiary lid to be attached to the trunk body instead of the tertiary lid and a transport buffer covering the outside of the trunk body can be attached and detached, and the opening in the trunk body A plurality of screw holes are formed along the circumferential direction on the outer side of each of the bolts, and screw portions of a plurality of bolts pass through the tertiary lid and are respectively tightened in the screw holes so that the tertiary lid can be attached to the trunk body. In addition, a plurality of bolt thread portions penetrate through the transport tertiary lid and are respectively tightened to a part of the screw holes so that the transport tertiary lid can be attached to the trunk body. It is preferable that the transport cushion can be attached to the trunk body by screwing the threaded portion through the transport cushion and tightening it to the other part of the screw hole. According to this radioactive substance storage container, since the screw hole can be used both during storage and transportation of the radioactive substance, the structure can be simplified.

  In the radioactive substance storage container, it is preferable that a transport buffer covering the outer side of the tertiary lid and the trunk body is detachable with respect to the trunk body. According to this radioactive substance storage container, the tertiary lid can also be used during storage and transportation of the radioactive substance.

  In the radioactive substance storage container, a plurality of screw holes are formed along a circumferential direction outside the opening in the trunk body, and a plurality of bolt thread portions penetrate through the tertiary lid and are part of the screw holes. The tertiary lid can be attached to the body body by being tightened to each other, and the threaded portions of a plurality of bolts can be tightened to other parts of the threaded holes through the transport buffer. It is preferable that the transport cushion is attachable to the trunk body. According to this radioactive substance storage container, when fixing the tertiary lid and the transport buffer, the screw holes can be partially shared with each other, so that the structure of the radioactive substance storage container can be simplified. .

  In the radioactive substance storage container, it is preferable that the tertiary lid has a disc shape and an opening is formed at a central portion. According to this radioactive substance storage container, by having the opening, the heat of the radioactive substance can be more suitably released to the outside.

  In the radioactive substance storage container, the tertiary lid is preferably a hollow member. According to this radioactive substance storage container, since the external impact is absorbed by the hollow tertiary lid, the impact resistance of the radioactive substance storage container can be suitably improved.

  In the radioactive substance storage container, it is preferable that the tertiary lid has a heat insulating portion inside. According to this radioactive substance storage container, it is possible to suppress external heat from being transmitted to the inside of the radioactive substance storage container by having the heat insulating portion inside the tertiary lid.

  In the radioactive substance storage container, it is preferable that an inclined surface tapering toward the opening in the longitudinal direction of the trunk body is provided on the outer peripheral surface of the cover portion. According to this radioactive substance storage container, since the impact can be released by the inclined surface, the impact resistance of the radioactive substance storage container can be suitably improved.

  The said radioactive substance storage container WHEREIN: It is preferable that the said tertiary lid | cover has the reinforcement member which connected the some plate-shaped member extended toward the outer side of the said tertiary lid | cover. According to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be improved by the reinforcing member.

  In the radioactive substance storage container, the cover part is provided with a holding part that holds a side surface of the trunk body, and the tertiary lid can be fixed to the trunk body by fastening the holding part to the trunk body. Preferably there is. According to this radioactive substance storage container, since an external impact is transmitted to the side surface of the trunk body via the holding portion, the impact is prevented from being transmitted to the secondary lid. Therefore, according to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be improved.

  In the radioactive substance storage container, it is preferable that a trunnion is provided on a side surface of the trunk body, and the cover portion can be fixed to the trunnion by a fixing portion. According to this radioactive substance storage container, an external impact is transmitted to the side surface of the trunk body via the fixing portion and the trunnion, and therefore, the impact is prevented from being transmitted to the secondary lid. Therefore, according to this radioactive substance storage container, the impact resistance of the radioactive substance storage container can be suitably improved.

  In the radioactive substance storage container, the tertiary lid is preferably filled with foam metal. According to this radioactive substance storage container, it is possible to suppress external heat from being transmitted to the inside of the radioactive substance storage container by the foam metal inside the tertiary lid.

  In order to solve the above-described problems and achieve the object, the radioactive substance storage and transport method of the present invention is applied to a radioactive substance storage container having a trunk body which is a cylindrical member having an opening at one end. A radioactive substance is stored, a primary lid is attached to the opening, a secondary lid is attached to the outside of the primary lid in the opening, and the secondary lid is externally attached to the outside of the secondary lid in the opening. Attach a tertiary lid that protects against the impact of the material, store the radioactive material, remove the tertiary lid, attach a tertiary lid for transportation to the outside of the secondary lid at the opening, and cover the outside of the trunk body A transport buffer is attached to the trunk body to transport the radioactive material. According to this method for storing and transporting radioactive materials, the tertiary lid is attached during storage, so that the impact resistance of the radioactive material storage container can be further improved.

  In the method for storing and transporting radioactive materials, a plurality of screw holes are formed along a circumferential direction outside the opening in the trunk body, and screw portions of a plurality of bolts pass through the tertiary lid to form the screw holes. The tertiary lid is attached to the body body by being tightened respectively, and a screw portion of a plurality of bolts penetrates the tertiary lid for transportation and is respectively tightened to a part of the screw hole to thereby attach the tertiary lid for transportation. It is preferable to attach the transport cushion to the trunk body by attaching the threaded portion of a plurality of bolts to the other portion of the thread portion through the transport cushion and attaching to the trunk body. . According to the method for storing and transporting radioactive materials, the structure of the radioactive material storage container can be simplified because the screw holes can be used both during storage and transportation of the radioactive materials.

  According to the present invention, the impact resistance of the radioactive substance storage container can be improved.

FIG. 1 is a longitudinal sectional view of a cask according to the first embodiment. FIG. 2 is a plan sectional view of the cask according to the first embodiment. FIG. 3 is a cross-sectional view of a main part of the cask according to the first embodiment. FIG. 4 is a plan view of the trunk body according to the first embodiment. FIG. 5 is a longitudinal sectional view of the cask according to the first embodiment when the radioactive material is transported. FIG. 6 is a cross-sectional view of a main part of the cask according to the first embodiment when the radioactive substance is transported. FIG. 7 is a longitudinal sectional view of a main part of the cask according to the second embodiment. FIG. 8 is a cross-sectional view of a main part of the cask according to the second embodiment when the radioactive material is transported. FIG. 9 is a cross-sectional view of a main part of a cask according to the first modification. FIG. 10 is a cross-sectional view of a main part of a cask according to the second modification. FIG. 11 is a cross-sectional view of a main part of a cask according to the third modification. FIG. 12 is a cross-sectional view of a main part of a cask according to the fourth modification. FIG. 13 is a plan view of a tertiary lid according to Modification 4. FIG. FIG. 14 is a front view of a cask according to the fifth modification. FIG. 15 is a cross-sectional view of a main part of a cask according to the fifth modification. FIG. 16 is a cross-sectional view of a main part of a cask according to the sixth modification.

(Embodiment 1)
Embodiment 1 will be described in detail with reference to the drawings. 1 is a longitudinal sectional view of a cask according to the first embodiment, and FIG. 2 is a plan sectional view of the cask according to the first embodiment.

  A cask 11 as a radioactive substance storage container includes a body portion 12, a lid portion 13, and a basket 14. The trunk portion 12 has a cylindrical shape in which an opening 22 is formed on one side of the trunk body 21, that is, an upper portion, and the bottom portion (blocking portion) 23 is formed on the other side, that is, a lower portion. For example, a spent fuel assembly) can be stored. That is, the trunk body 21 is provided with a cavity 24 inside, and the cavity 24 has a shape matching the outer peripheral shape of the basket 14. The basket 14 has a plurality of cells that individually store a plurality of radioactive substances (not shown). The basket 14 has a basket body 14A as shown in FIG. In the basket body 14A, radioactive substance storage portions 14B as cells arranged parallel to each other at a predetermined interval are formed continuously in the vertical direction. The vertical direction is a direction along the cylindrical longitudinal direction X of the trunk body 21 in the cask 11 and corresponds to the vertical direction of the trunk body 21. And the bottom part 23 of the trunk | drum main body 21 is couple | bonded or integrally molded by welding, and this trunk | drum main body 21 and the bottom part 23 are forged products made from carbon steel which has a gamma ray shielding function. The trunk body 21 and the bottom 23 can be made of stainless steel instead of carbon steel. The trunk body 21 and the bottom portion 23 can also be made of cast products such as spheroidal graphite cast iron or carbon steel cast steel.

  The body portion 12 is provided with an outer cylinder 25 with a predetermined gap on the outer peripheral side of the body main body 21, and conducts heat between the outer peripheral surface of the body main body 21 and the inner peripheral surface of the outer cylinder 25. A plurality of heat transfer fins 25A made of copper or steel are welded at equal intervals in the circumferential direction. The body 12 is a resin (neutron shielding body) 26 containing boron or a boron compound which is a polymer material containing a large amount of hydrogen and has a neutron shielding function in the space between the body body 21 and the outer cylinder 25. Is injected and solidified through a pipe (not shown) in a fluidized state.

  The body 12 may have a bottom plate 28 connected to the lower side of the bottom 23 with a plurality of connecting plates 27 with a predetermined gap, and a resin (neutron) in a space between the connecting plate 27 and the bottom plate 28. A shield) 29 is provided. Further, the trunnion 29 is fixed to the side surface 35 of the trunk portion 12. The connecting plate 27 may not be provided.

  As shown in FIG. 1, the lid portion 13 includes a primary lid 31, a secondary lid 32, and a tertiary lid 33. The primary lid 31 is detachably attached to the opening 22. The secondary lid 32 is detachably attached to the outside of the primary lid 31 in the opening 22. The tertiary lid 33 is detachably attached to the outside of the secondary lid 32 in the opening 22. Although described in detail later, the tertiary lid 33 protects the secondary lid 32 from external impacts. Further, between the primary lid 31 and the secondary lid 32, a buffer part 34 that absorbs the impact of the secondary lid 32 may be provided. Next, the attachment of the primary lid 31, the secondary lid 32, and the tertiary lid 33 to the opening 22 will be described in detail.

  FIG. 3 is a cross-sectional view of a main part of the cask according to the first embodiment. FIG. 4 is a plan view of the trunk body 21 according to the first embodiment. As shown in FIG. 3, the inner periphery of the opening 22 is stepped. That is, the first step portion 81, the second step portion 82, and the third step portion 83 are provided on the inner peripheral portion of the opening 22.

  The first step portion 81 has a first inner peripheral portion 74 and a first seat surface portion 77. The first inner peripheral portion 74 is the inner periphery of the trunk body 21. The first seat surface portion 77 extends from the end on the opening 22 side in the longitudinal direction X of the first inner peripheral portion 74 to the outside in the radial direction of the trunk body 21. As shown in FIG. 4, the first seat surface portion 77 is provided with a plurality of screw holes 63 along the circumference. In FIG. 4, the number of screw holes 63 is eight, but is not limited thereto. As will be described in detail later, the primary lid 31 is fixed to the trunk body 21 at the first step portion 81.

  The second step portion 82 is located closer to the opening 22 than the first step portion 81 in the longitudinal direction X. The second step portion 82 has a second inner peripheral portion 75 and a second seat surface portion 78. The second inner peripheral portion 75 is the inner periphery of the trunk body 21 and extends from the outer periphery of the first seat surface portion 77 toward the opening 22 in the longitudinal direction X. The second seat surface portion 78 extends outward in the radial direction of the trunk body 21 from the end portion on the opening portion 22 side in the longitudinal direction X of the second inner peripheral portion 75. As shown in FIG. 4, the second seat surface portion 78 is provided with a plurality of screw holes 64 along the circumference. In FIG. 4, the number of the screw holes 64 is eight, but is not limited thereto. As will be described in detail later, the secondary lid 32 is fixed to the trunk body 21 at the second step portion 82.

  The third step portion 83 is located closer to the opening 22 than the second step portion 82 in the longitudinal direction X. The third step portion 83 has a third inner peripheral portion 76 and a third seat surface portion 79. The third inner periphery 76 is the inner periphery of the trunk body 21 and extends from the outer periphery of the second seat surface portion 78 toward the opening 22 in the longitudinal direction X. The third seat surface portion 79 extends outward in the radial direction of the trunk body 21 from the end portion on the opening 22 side in the longitudinal direction X of the third inner peripheral portion 76. The third seat surface portion 79 forms an end surface on the opening 22 side in the longitudinal direction X of the trunk body 21. In other words, the third seat surface portion 79 is an end surface provided outside the opening 22.

  As shown in FIG. 4, screw holes 65A, 65B, 65C, 65D, 65E, 65F, 65G, 65H, 65I, 65J, 65K, 65L, 65M, 65N, 65O, and 65P are formed in the third seat surface portion 79. Are provided along the circumferential direction. Hereinafter, when it is not necessary to distinguish the screw holes 65A to 65P from each other, they are referred to as screw holes 65. The number of screw holes 65 is not limited to 16 from 65A to 65P. As will be described in detail later, the tertiary lid 33 is fixed to the trunk body 21 at the third step portion 83. Next, the primary lid 31 will be described.

  The primary lid 31 is made of, for example, carbon steel or stainless steel. As shown in FIG. 3, the primary lid 31 has a protruding portion 41 and a disc portion 42. The protrusion 41 is provided at the center of the end surface 71 that is one end surface of the disc portion 42. The primary lid 31 is attached to the opening 22 by inserting the protruding portion 41 into the first inner peripheral portion 74 and bringing the end surface 71 and the first seat surface portion 77 into contact with each other. The primary lid 31 may be provided with a resin.

  A gasket groove 51 is provided on the end surface 71. In the gasket groove 51, for example, a gasket 59 which is a metal gasket is attached. The gasket 59 is sandwiched between the gasket groove 51 and the first seat surface portion 77. When the gasket 59 is sandwiched between the gasket groove 51 and the first seat surface portion 77, the gasket 59 seals between the first step portion 81 and the primary lid 31. Thereby, the primary lid 31 can seal the trunk body 21.

  The disc portion 42 is provided with a plurality of through holes 52 along the circumferential direction. When the end surface 71 and the first seat surface portion 77 are brought into contact with each other, the through hole 52 and the screw hole 63 can be aligned with each other. The plurality of bolts 60 are respectively penetrated through the plurality of through holes 52, and the screw portions 84 and the screw holes 63 of the bolts 60 are tightened. The primary lid 31 is fixed to the opening 22 by tightening the screw portion 84 and the screw hole 63. The through hole 52 has a seat surface portion 53 on the surface opposite to the end surface 71 of the disc portion 42. The seat surface portion 53 forms a seat surface of the bolt 60. Next, the secondary lid 32 will be described.

  The secondary lid 32 is made of, for example, carbon steel or stainless steel. As shown in FIG. 3, the secondary lid 32 has a protruding portion 43 and a disc portion 44. The protrusion 43 is provided at the center of the end surface 72 that is one end surface of the disc portion 44. The secondary lid 32 is attached to the opening 22 by inserting the protruding portion 43 into the second inner peripheral portion 75 and bringing the end surface 72 and the second seat surface portion 78 into contact with each other. In addition, the protrusion 43 may be provided with a recess covering the buffer portion 34 at the center thereof. In addition, the secondary lid 32 is provided with an inspection through hole 90 that communicates a space 96 between the primary lid 31 and the secondary lid 32. The inspection through hole 90 has a storage portion 95 on the surface opposite to the end surface 72 of the secondary lid 32. The storage unit 95 is provided with a pressure sensor 91 that measures the pressure of the space 96. The secondary lid 32 may be provided with a resin.

  A gasket groove 54 is provided on the end surface 72. A gasket 80, which is a metal gasket, for example, is attached to the gasket groove 54. The gasket 80 is sandwiched between the gasket groove 54 and the second seat surface portion 78. By sandwiching the gasket 80 between the gasket groove 54 and the second seat surface portion 78, the gasket 80 seals between the second step portion 82 and the secondary lid 32. Thereby, the secondary lid 32 can seal the trunk body 21.

  The disc portion 44 is provided with a plurality of through holes 55 along the circumferential direction. When the end surface 72 and the second seat surface portion 78 are brought into contact with each other, the through hole 55 and the screw hole 64 can be aligned with each other. The plurality of bolts 61 are respectively inserted into the plurality of through holes 55, and the screw portions 85 and the screw holes 64 of the bolts 61 are tightened. The secondary lid 32 is fixed to the opening 22 by tightening the screw portion 85 and the screw hole 64. The through hole 55 has a seat surface portion 56 on the surface opposite to the end surface 72 of the disc portion 44. The seat surface portion 56 forms a seat surface of the bolt 61. Next, the tertiary lid 33 will be described.

  As shown in FIG. 3, the tertiary lid 33 includes a protruding portion 45, a disc portion 46, and a cover portion 47. The tertiary lid 33 is made of a metal such as carbon steel, stainless steel, or aluminum, for example. The protrusion 45 is provided at the center of the end surface 73 that is one end surface of the disc portion 46. The cover portion 47 is provided on the outer periphery of the disc portion 46 and extends in the direction of the end surface 73 of the disc portion 46. The tertiary lid 33 is attached to the opening 22 by inserting the protruding portion 45 into the third inner peripheral portion 76 and bringing the end surface 73 and the third seat surface portion 79 into contact with each other.

  The disc part 46 is provided with a plurality of through holes 57 along the circumferential direction. When the end surface 73 and the third seat surface portion 79 are brought into contact with each other, the through hole 57 and the screw hole 65 can be aligned with each other. The plurality of bolts 62 are respectively inserted into the plurality of through holes 57, and the screw portions 86 and the screw holes 65 of the bolts 62 are tightened. The tertiary lid 33 is fixed to the opening 22 by tightening the screw portion 86 and the screw hole 65. The through hole 57 has a seating surface portion 58 on the surface opposite to the end surface 73 of the disc portion 46. The seat surface portion 58 forms a seat surface of the bolt 62. A part of the screw hole 65 may be used when the tertiary lid 33 is fixed to the opening 22.

  When the tertiary lid 33 is attached to the trunk body 21, a first space 66 may be formed between the secondary lid 32 and the tertiary lid 33. The cover 47 covers at least a part of the side surface 35 that is the outer periphery of the trunk body 21. Further, the cover portion 47 covers the side surface of the secondary lid 32. A second space 67 may be formed between the cover portion 47 and the side surface 35.

  The tertiary lid 33 may be provided with a drawing hole 93 for pulling out the lead wire 92 of the pressure sensor 91 to the outside. Further, the lead-out hole 93 may have a seal portion 94 such as hermetic on the surface opposite to the end surface 73 of the tertiary lid 33. The seal portion 94 can seal the extraction hole 93.

  The radioactive substance is stored in the cask 11 and stored by attaching the primary lid 31, the secondary lid 32, and the tertiary lid 33 to the trunk body 21 as described above. Next, transportation of radioactive material by the cask 11 will be described.

  FIG. 5 is a longitudinal sectional view of the cask according to the first embodiment when the radioactive material is transported. FIG. 6 is a cross-sectional view of a main part of the cask according to the first embodiment when the radioactive substance is transported. 5 and 6 show the form of the cask 11 when the radioactive material is transported by the cask 11. As shown in FIG. 5, the tertiary lid 33 is removed when the radioactive substance is transported, and a transport tertiary lid 36 and a transport buffer 37 are attached instead. The transport buffer 37 covers the trunk body 21. For example, the transport buffer 37 covers at least a part of the side surface 35.

  As shown in FIG. 6, the transportation tertiary lid 36 includes a protruding portion 101 and a disc portion 102. The protrusion 101 is provided at the center of the end surface 103 which is one end surface of the disc portion 102. The tertiary transport lid 36 is attached to the opening 22 by inserting the protrusion 101 into the third inner peripheral portion 76 and bringing the end surface 103 and the third seat surface 79 into contact with each other. The outer diameter of the disc part 102 is smaller than the outer diameter of the trunk body 21.

  A gasket groove 104 is provided on the end surface 103. A gasket 105, which is a rubber gasket, for example, is attached to the gasket groove 104. The gasket 105 is sandwiched between the gasket groove 104 and the third seat surface portion 79. By sandwiching the gasket 105 between the gasket groove 104 and the third seat surface portion 79, the gasket 105 seals between the third step portion 83 and the transport tertiary lid 36. Therefore, the transport tertiary lid 36 seals the cask 11 when the radioactive material is transported.

  The disc portion 102 is provided with a plurality of through holes 106 along the circumferential direction. When the end surface 103 and the third seat surface portion 79 are brought into contact with each other, the positions of the through hole 106 and the screw hole 65X that is a part of the plurality of screw holes 65 can be aligned. The plurality of bolts 108 are respectively inserted into the plurality of through holes 106, and the screw portions 109 and the screw holes 65X of the bolts 108 are tightened. By tightening the screw portion 109 and the screw hole 65 </ b> X, the transport tertiary lid 36 is fixed to the opening 22. The through-hole 106 has a seat surface portion 107 on an end surface 112 that is a surface opposite to the end surface 103 of the disc portion 102. The seat surface portion 107 forms a seat surface of the bolt 108. The detailed arrangement of the screw holes 65X will be described later.

  The transport buffer 37 is manufactured, for example, by attaching a wooden member to a metal frame. The transport buffer 37 serves as a buffer for the cask 11 when the radioactive substance is transported. As shown in FIG. 6, the transport cushion 37 includes a disc part 110 and a cover part 111. The cover portion 111 extends from the outer periphery of the disc portion 110 in the direction of the end surface 113 that is one end surface of the disc portion 110. The transport buffer 37 is attached to the trunk body 21 by attaching the inner circumference of the cover portion 111 to the outer circumference of the trunk body 21 from the direction of the opening 22 and bringing the end face 113 and the end face 112 into contact with each other. The disc part 110 covers the transportation tertiary lid 36, and the cover part 111 covers at least a part of the side surface 35. The transport buffer may be attached to the bottom 23 as well.

  A plurality of through-holes 115 are provided in the disk portion 110 of the transport buffer 37 along the circumferential direction. In addition, a plurality of through holes 114 are provided in the disc portion 102 of the transport tertiary lid 36 along the circumferential direction. The through hole 114 is provided concentrically with the through hole 106. When the end surface 112 and the end surface 113 are in contact with each other, the through hole 114 and the through hole 115 are aligned with each other. Further, the screw hole 65 </ b> Y which is another part of the plurality of screw holes 65 is aligned with the through hole 114 and the through hole 115. The plurality of bolts 117 are respectively inserted into the plurality of through holes 114 and 115, and the screw portion 118 and the screw hole 65Y of the bolt 117 are tightened. The buffer body for transport 37 is fixed to the trunk body 21 by tightening the screw portion 118 and the screw hole 65Y. The through hole 115 has a seat surface portion 116 on the end surface opposite to the end surface 113 of the disc portion 110. The seat surface portion 116 forms a seat surface of the bolt 117. The through hole 114 may have the same shape as the through hole 106. Next, the arrangement of the screw holes 65X and the screw holes 65Y will be described.

  As shown in FIG. 4, the screw hole 65X includes screw holes 65A, 65C, 65E, 65G, 65I, 65K, 65M, and 65O. The screw hole 65Y includes screw holes 65B, 65D, 65F, 65H, 65J, 65L, 65N, and 65P. As described above, the screw holes 65X are obtained by selecting every other screw hole 65 from the screw hole 65A along the circumferential direction. The screw holes 65Y are obtained by selecting every other screw hole 65 from the screw hole 65B along the circumferential direction. However, the screw hole 65X and the screw hole 65Y are not limited to this arrangement. The screw hole 65X is a part of the screw hole 65, and the screw hole 65Y may be another part of the screw hole 65.

  As described above, the tertiary lid 33 is fixed to the trunk body 21 by tightening the screw portion 86 and the screw hole 65 through the through hole 57. Further, the transport tertiary lid 36 is fixed to the trunk body 21 by tightening the screw portion 109 and the screw hole 65X through the through hole 106. Further, the transport buffer 37 is fixed to the trunk body 21 by tightening the screw part 118 and the screw hole 65Y through the through holes 114 and 115. That is, the screw hole 65 is used for fixing the tertiary lid 33 when the radioactive substance is stored, and is used for fixing the tertiary lid 36 for transportation and the buffer body 37 for transportation when the radioactive substance is transported.

  The tertiary lid 33 is attached to the outside of the secondary lid 32 and covers the secondary lid 32. Accordingly, the tertiary lid 33 protects the secondary lid 32 from external impacts. For example, when an aircraft accident occurs, a flying object may collide with the cask 11. In such a case, a collision of flying objects generates a strong impact. The cask 11 according to the first embodiment includes a tertiary lid 33 that covers the secondary lid 32. The tertiary lid 33 prevents flying objects from directly colliding with the secondary lid 32 and protects the secondary lid 32 from impact. Therefore, the cask 11 according to the first embodiment has improved impact resistance by having the tertiary lid 33. Therefore, for example, even when there is an aircraft accident, the cask 11 prevents the inside seal from being maintained. Furthermore, the tertiary lid 33 can protect the secondary lid 32 from a fire caused by an aircraft accident or the like.

  Further, when an impact is applied to the side surface of the secondary lid 32 via the side surface 35 of the trunk body 21, for example, the secondary lid 32 is laterally displaced with respect to the trunk body 21, and the secondary lid 32 can seal the trunk body 21. There is a possibility of disappearing. However, the tertiary lid 33 has a cover portion 47. The cover portion 47 covers the side surface 35 of the trunk main body 21 and thus protects the secondary lid 32 from an impact on the side surface of the secondary lid 32.

  The tertiary lid 33 is made of metal. Therefore, the tertiary lid 33 improves the impact resistance and fire resistance of the cask 11 more suitably. Moreover, the tertiary lid | cover 33 can escape the heat | fever from a radioactive substance suitably outside.

  In the first embodiment, the cask 11 includes a first space 66 between the secondary lid 32 and the tertiary lid 33. The first space 66 more suitably protects the secondary lid 32 from external impacts. For example, even when the tertiary lid 33 is deformed by an external impact, the first space 66 prevents the deformed tertiary lid 33 from coming into contact with the secondary lid 32 or alleviates the impact. . Similarly, the cask 11 has a second space 67 between the cover portion 47 and the side surface 35 of the trunk body 21. Therefore, the second space 67 more suitably protects the secondary lid 32 from external impacts. For example, when there is an impact on the cover portion 47 from the side surface, the second space 67 prevents the cover portion 47 from contacting the side surface 35 or reduces the impact. Further, for example, when the cover 47 has an impact from the side, the bolt 62 and the second space 67 can absorb the impact.

  Furthermore, in Embodiment 1, the tertiary lid | cover 33 is attached at the time of storage of a radioactive substance, and the tertiary lid | cover 36 for transportation and the buffer body 37 for transportation are attached at the time of transportation of a radioactive substance. Accordingly, the cask 11 protects the secondary lid 32 from impact during storage. The cask 11 can maintain the sealing performance by the transport tertiary lid 36 during transport.

  The screw hole 65 is used for fixing the tertiary lid 33 when the radioactive substance is stored, and is used for fixing the tertiary lid 36 for transportation and the buffer body 37 for transportation when the radioactive substance is transported. That is, the cask 11 can also serve as the screw hole 65 when the radioactive substance is stored and transported. Therefore, the structure of the cask 11 can be simplified.

(Embodiment 2)
Next, Embodiment 2 will be described in detail with reference to the drawings. FIG. 7 is a longitudinal sectional view of a main part of the cask according to the second embodiment. The cask 11a according to the second embodiment is different from the cask 11 according to the first embodiment in the shape of the tertiary lid. The cask 11a also serves as a tertiary lid when the radioactive substance is stored and transported. Since the second embodiment is the same as the first embodiment in other points, the description of the overlapping parts is omitted.

  As shown in FIG. 7, the cask 11a has a tertiary lid 33a. The tertiary lid 33a is used for storing radioactive materials. The tertiary lid 33 a is detachably attached to the outside of the secondary lid 32 in the opening 22. The tertiary lid 33a protects the secondary lid 32 from external impacts.

  The tertiary lid 33a is made of, for example, a metal such as carbon steel, stainless steel, or aluminum. As shown in FIG. 7, the tertiary lid 33a has a protrusion 45a and a disk portion 46a. The protrusion 45a is provided at the center of the end surface 73a, which is one end surface of the disc portion 46a. The tertiary lid 33a is attached to the opening 22 by inserting the protrusion 45a into the third inner peripheral portion 76 and bringing the end surface 73a and the third seat surface portion 79 into contact with each other. The outer diameter of the disc portion 46 a is larger than the outer diameter of the trunk body 21.

  A gasket groove 121a is provided on the end surface 73a. For example, a gasket 122a, which is a rubber gasket, is attached to the gasket groove 121a. The gasket 122 a is sandwiched between the gasket groove 121 a and the third seat surface portion 79. By sandwiching the gasket 122a between the gasket groove 121a and the third seat surface portion 79, the gasket 122a seals between the third step portion 83 and the tertiary lid 33a.

  The disc portion 46a is provided with a plurality of through holes 57a along the circumferential direction. When the end surface 73a and the third seat surface portion 79 are brought into contact with each other, the positions of the through hole 57a and the screw hole 65X can be matched. The plurality of bolts 62a are respectively inserted into the plurality of through holes 57a, and the screw portions 86a and the screw holes 65X of the bolts 62a are tightened. The tertiary lid 33a is fixed to the opening 22 by tightening the screw portion 86a and the screw hole 65X. The through hole 57a has a seating surface portion 58a on the end surface 120a which is the surface opposite to the end surface 73a of the disc portion 46a. The seat surface portion 58a forms a seat surface of the bolt 62a.

  When the tertiary lid 33a is attached to the trunk body 21, a first space 66a may be formed between the secondary lid 32 and the tertiary lid 33a. Moreover, the tertiary lid 33a may have a cover part on the outer periphery of the disc part 46a similarly to the tertiary lid 33 according to the first embodiment.

  As described above, the radioactive substance is stored in the cask 11a and stored by attaching the primary lid 31, the secondary lid 32, and the tertiary lid 33a to the trunk body 21. Next, transportation of radioactive material by the cask 11a will be described.

  FIG. 8 is a cross-sectional view of a main part of the cask according to the second embodiment when the radioactive material is transported. As shown in FIG. 8, when the cask 11a according to the second embodiment transports a radioactive substance, a transport buffer 37 that covers the outer side of the tertiary lid 33a and the outer side of the trunk body 21 is attached. In other words, unlike the first embodiment, the cask 11a according to the second embodiment also serves as the tertiary lid 33a when the radioactive material is stored and transported.

  As shown in FIG. 8, the transport buffer 37 is attached to the outer periphery of the body portion 21 from the direction of the opening 22 with the inner periphery of the cover 111, and the end surface 113 of the transport buffer 37 and the end surface of the tertiary lid 33a. It is attached to the trunk body 21 by abutting 120a. The disc part 110 covers the opening 22, and the cover part 111 covers at least a part of the side surface 35.

  A plurality of through holes 114a are provided in the disc portion 46a of the tertiary lid 33a along the circumferential direction. The through hole 114a is provided concentrically with the through hole 57a. When the end surface 113 and the end surface 120a abut, the through hole 114a and the through hole 115 are aligned with each other. The screw hole 65Y is aligned with the through hole 114a and the through hole 115. The plurality of bolts 117 are respectively inserted into the plurality of through holes 114 a and 115, and the threaded portion 118 of the bolt 117 and the screw hole 65 Y are tightened, whereby the transport buffer 37 is fixed to the trunk body 21. The through hole 114a may have the same shape as the through hole 57a.

  As described above, the tertiary lid 33a is fixed to the trunk body 21 by tightening the screw portion 86a and the screw hole 65X via the through hole 57a. Further, the transport buffer 37 is fixed to the trunk body 21 by tightening the screw portion 118 and the screw hole 65Y through the through holes 115 and 114a. That is, the screw hole 65 is used for fixing the tertiary lid 33a and the transport buffer 37. In addition, the tertiary lid | cover 33a may be fixed to the trunk | drum main body 21 using all the several screw holes 65 at the time of storage of a radioactive substance. In this case, when the radioactive substance is transported, the bolt attached to the screw hole 65Y is removed, and the screw hole 65Y is used to fix the transport buffer 37.

  Similar to the first embodiment, the cask 11a according to the second embodiment has improved impact resistance by having the tertiary lid 33a. Further, the tertiary lid 33a can protect the secondary lid 32 from a fire caused by an aircraft accident or the like.

  Moreover, the tertiary lid | cover 33a is shared at the time of storage and transportation of a radioactive substance. Therefore, the cask 11a according to the second embodiment can reduce the work load when transporting the stored radioactive material. The screw hole 65 is used for fixing the tertiary lid 33a and the transport buffer 37. That is, the cask 11a can be used by partially sharing the screw holes 65 when the tertiary lid 33a and the transport buffer 37 are fixed. Therefore, the structure of the cask 11a can be simplified.

(Modification 1)
Next, a first modification of the cask according to the first embodiment will be described. FIG. 9 is a cross-sectional view of a main part of a cask according to the first modification. The cask 11b according to Modification 1 has an opening at the center of the tertiary lid. Since the modification 1 is the same as that of Embodiment 1 in other points, description of the overlapping part is abbreviate | omitted.

  As shown in FIG. 9, the tertiary lid 33 b according to the first modification includes a protrusion 45 b, a disk part 46 b, and a cover part 47 b as in the first embodiment. Moreover, the tertiary lid | cover 33b has the opening part 130b which penetrates the tertiary lid | cover 33b in the center part of the disc part 46b. The opening 130b communicates the first space 66b with the outside of the cask 11b.

  The side surface of the secondary lid 32 is less impact resistant than the other parts. For example, when the secondary lid 32 receives an impact through the side surface 35 of the trunk body 21, the secondary lid 32 may not be able to seal the trunk body 21. The tertiary lid 33b according to the modified example 1 covers the side surface of the secondary lid 32 by the disc portion 46b and the cover portion 47b. Accordingly, the cask 11b has the tertiary lid 33b, so that the impact resistance is improved.

  The tertiary lid 33b has an opening 130b. Since the opening 130b communicates the first space 66b with the outside of the cask 11b, the heat of the radioactive substance can be more suitably released to the outside. In addition, the opening part 130b does not need to be provided in the center part of the disc part 46b. As long as the disc part 46b and the cover part 47b cover the side surface of the secondary lid 32, the opening part 130b may be provided at an arbitrary position of the disc part 46b.

  The tertiary lid 33b may be filled with foam metal. Alternatively, the tertiary lid 33b may be made of a foam metal. Since the foam metal has pores inside, for example, in the event of a fire, it is possible to more suitably suppress heat from being transmitted to the secondary lid 32. In this case, the tertiary lid 33b may not have the opening 130b.

(Modification 2)
Next, a second modification of the cask according to the first modification will be described. FIG. 10 is a cross-sectional view of a main part of a cask according to the second modification. The cask 11c according to the second modification is a member having a hollow tertiary lid. Since Modification 2 is the same as Modification 1 in other points, description of the overlapping parts is omitted.

  Similar to the first modification, the tertiary lid 33c according to the second modification includes a protrusion 45c, a disk portion 46c, a cover 47c, and an opening 130c. The tertiary lid 33c is a hollow member, and has a hollow portion 131c inside. Since the tertiary lid 33c has the hollow portion 131c, it buckles when a flying object collides, for example. The tertiary lid 33c can absorb collision energy by buckling. Accordingly, the cask 11c has improved impact resistance by having the tertiary lid 33c. Moreover, the tertiary lid | cover 33c may provide a heat insulating material in the hollow part 131c. By providing a heat insulating material in the hollow portion 131c, for example, in the event of a fire, it is possible to more suitably suppress heat from being transmitted to the inside of the secondary lid 32 and the cask 11c. The tertiary lid 33c may not have the opening 130c.

(Modification 3)
Next, a cask modification 3 according to the modification 1 will be described. FIG. 11 is a cross-sectional view of a main part of a cask according to the third modification. As for the cask 11d which concerns on the modification 3, the cover part of a tertiary cover inclines. Since Modification 3 is the same as Modification 1 in other points, description of the overlapping parts is omitted.

  Similar to the first modification, the tertiary lid 33d according to the third modification includes a protrusion 45d, a disk 46d, a cover 47d, and an opening 130d. The cover portion 47d has an inclined surface portion 132d that tapers toward the opening 22 in the longitudinal direction X on the outer peripheral surface. When the tertiary lid 33d receives an impact from the side surface, the tertiary lid 33d can release the impact in the direction Y along the inclined surface portion 132d. Therefore, the cask 11d according to the modified example 3 has the inclined surface portion 132d, thereby improving the impact resistance. The tertiary lid 33d may not have the opening 130d.

  The inclined surface portion 132d may have a shape that tapers toward the bottom 23 in the longitudinal direction X. In this case, the impact is released from the side surface toward the side surface 35 of the trunk body 21. In this case, the tertiary lid 33 d can release the impact on the secondary lid 32 to the side surface 35. Therefore, the tertiary lid 33d can protect the secondary lid 32 more suitably.

(Modification 4)
Next, a modified example 4 of the cask according to the first embodiment will be described. FIG. 12 is a cross-sectional view of a main part of a cask according to the fourth modification. FIG. 13 is a plan view of a tertiary lid according to Modification 4. FIG. The cask 11e according to Modification 4 has a reinforcing member on the tertiary lid. Since the modification 4 is the same as that of Embodiment 1 in other points, description of the overlapping part is abbreviate | omitted.

  As shown in FIG. 12, the tertiary lid 33e according to the modified example 4 includes a protrusion 45e, a disk part 46e, and a cover part 47e as in the first embodiment. The protrusion 45e is provided at the center of one end surface 73e of the disc part 46e. As shown in FIG. 13, the disc portion 46 e has a plurality of through holes 57 e and a seat surface portion 58 e.

  The tertiary lid 33e has a reinforcing member 133e. As shown in FIG. 13, the reinforcing member 133e has a plurality of plate-like members 135e and a connecting portion 136e. The connection part 136e is provided in the center part of the end surface 134e. The plurality of plate-like members 135e are provided along the radial direction from the connecting portion 136e toward the outer periphery of the disc portion 46e.

  More specifically, the plate-like member 135e has a side surface 137e. The side surface 137e is provided on the other end surface 134e of the disc portion 46e from the connecting portion 136e toward the outer periphery of the disc portion 46e. The side surface 137e is provided on the outer periphery of the cover portion 47e from the outer periphery of the disc portion 46e toward the end surface 138e of the cover portion 47e. The plate-like member 135e extends from the side surface 137e toward the outside of the tertiary lid 33e. And each plate-shaped member 135e is connected by the connection part 136e, and forms the reinforcement member 133e. The reinforcing member 133e is not limited to this shape, and may be a shape in which a plurality of plate-like members extending toward the outside of the tertiary lid 33e are connected.

  As described above, the tertiary lid 33e according to the modification 4 includes the reinforcing member 133e. Since the reinforcing member 133e functions as a rib of the tertiary lid 33e, the cask 11e according to the modified example 4 has improved impact resistance. In addition, although the reinforcing member 133e was attached to the disc part 46e and the cover part 47e, the tertiary cover 33e may be manufactured only with the reinforcing member 133e.

(Modification 5)
Next, a modified example 5 of the cask according to the first embodiment will be described. FIG. 14 is a front view of a cask according to the fifth modification. FIG. 15 is a cross-sectional view of a main part of a cask according to the fifth modification. As for the cask 11f which concerns on the modification 5, a tertiary cover is fixed to the side surface of a trunk | drum main body. Since the modification 5 is the same as that of Embodiment 1 in other points, description of the overlapping part is abbreviate | omitted.

  As shown in FIGS. 14 and 15, the tertiary lid 33 f according to the modified example 5 includes a protruding portion 45 f, a disc portion 46 f, and a cover portion 47 f as in the first embodiment. The end surface 138f of the cover portion 47f is located on the bottom 23 side of the secondary lid 32 in the longitudinal direction X. A holding portion 140f is attached to the end surface 138f. As will be described in detail later, the holding portion 140 f holds the side surface 35 of the trunk body 21.

  The holding portion 140f has, for example, a shape in which a part of the annular member is missing. The inner diameter of the holding portion 140f is smaller than the inner diameter of the cover portion 47f and larger than the outer diameter of the trunk body 21. The holding portion 140f has one end portion 141f and the other end portion 142f along the circumferential direction. One end 141f has a through hole 146f, and the other end 142f has a through hole 147f. Next, a method for attaching the tertiary lid 33f to the trunk body 21 will be described.

  The tertiary lid 33f is attached to the opening 22 by inserting the protruding portion 45f into the third inner peripheral portion 76 and bringing the end surface 73f and the third seat surface portion 79 into contact with each other. A bolt 143f is attached to one end 141f. That is, the screw part 148f of the bolt 143f is penetrated through the through hole 146f and the through hole 147f. The seating surface of the bolt 143f is in contact with one end portion 141f. Then, the nut 144f is fastened to the screw portion 148f from the other end portion 142f side. The other end 142f forms a seating surface of the nut 144f.

  By tightening the nut 144f and the thread portion 148f, the inner periphery 145f of the holding portion 140f tightens the side surface 35 of the trunk body 21. When the inner periphery 145f tightens the side surface 35, the tertiary lid 33f is fixed to the trunk body 21. In addition, the fixing method to the trunk | drum main body 21 by the holding | maintenance part 140f is not restricted to this. The tertiary lid 33f may be fixed to the trunk body 21 by a holding portion that holds the side surface 35.

  As described above, the tertiary lid 33f according to the modified example 5 is fixed to the side surface 35 of the trunk body 21 by the holding portion 140f. Therefore, the tertiary lid 33f according to the modified example 5 transmits the impact to the side surface 35 via the holding portion 140f when receiving an impact from the outside. Therefore, the tertiary lid 33 f can suppress the impact transmitted to the secondary lid 32. Furthermore, since the holding part 140f is located on the bottom 23 side in the longitudinal direction X with respect to the secondary lid 32, the impact of the holding part 140f is more preferably suppressed from being transmitted to the secondary lid 32. Accordingly, the tertiary lid 33f can more suitably protect the secondary lid 32 from external impacts.

(Modification 6)
Next, a sixth modification of the cask according to the first embodiment will be described. FIG. 16 is a cross-sectional view of a main part of a cask according to the sixth modification. In the cask 11g according to the modified example 6, the tertiary lid is fixed to the trunnion 29. Since the modification 6 is the same as that of Embodiment 1 in other points, description of the overlapping part is abbreviate | omitted.

  As shown in FIG. 16, the tertiary lid 33g according to the modified example 6 includes a protrusion 45g, a disk part 46g, and a cover part 47g, as in the first embodiment. The end surface 138g of the cover portion 47g is located closer to the bottom portion 23 than the secondary lid 32 in the longitudinal direction X. A fixed portion 150g is attached to the end surface 138g.

  The fixing portion 150g has, for example, a flange portion 151g. The fixing portion 150g engages the hook portion 151g with the latching portion 29A of the trunnion 29. The cover portion 47g is fixed to the trunk body 21 via the trunnion 29 by engaging the flange portion 151g with the latching portion 29A. In the sixth modification, the flange portion 151g is fixed by engaging with the latching portion 29A, but is not limited thereto as long as the fixing portion 150g is fixed to the trunnion 29. For example, the fixing portion 150g may be fixed to the trunnion 29 with, for example, a bolt and a nut.

  As described above, the tertiary lid 33g according to the modified example 6 is fixed to the side surface 35 of the trunk body 21 via the fixing portion 150g and the trunnion 29. Therefore, the tertiary lid 33g according to the modified example 6 transmits the impact to the side surface 35 via the fixing portion 150g when receiving an impact from the outside. Therefore, the tertiary lid 33g can suppress the impact transmitted to the secondary lid 32. Furthermore, since the fixing portion 150g is located closer to the bottom 23 in the longitudinal direction X than the secondary lid 32, the impact of the fixing portion 150g is more preferably suppressed from being transmitted to the secondary lid 32. Accordingly, the tertiary lid 33g can more suitably protect the secondary lid 32 from external impacts.

  As mentioned above, although embodiment and the modification of this invention were demonstrated, these embodiment etc. are not limited by the content of these embodiment etc. In addition, the above-described constituent elements include those that can be easily assumed by those skilled in the art, those that are substantially the same, and those in a so-called equivalent range. Furthermore, the above-described components can be appropriately combined. Furthermore, various omissions, substitutions, or changes of the constituent elements can be made without departing from the spirit of the above-described embodiments and the like.

11 Cask 12 Body 13 Lid 21 Body Body 22 Opening 23 Bottom (Closing)
29 Trunnion 31 Primary lid 32 Secondary lid 33 Tertiary lid 36 Transport tertiary lid 37 Transport cushion 45 Projection portion 46 Disc portion 47 Cover portion 65 Screw hole 66 First space 67 Second space 81 First step portion 82 Second step 83 Third step X Longitudinal direction

Claims (14)

A cylinder body having an opening at one end, and a trunk body capable of containing a radioactive substance therein;
A primary lid detachably attached to the opening;
A secondary lid detachably attached to the outside of the primary lid in the opening;
A tertiary lid detachably attached to the outside of the secondary lid in the opening and protecting the secondary lid from external impacts;
I have a,
The secondary lid is separated from the primary lid over the entire surface via a lower space,
The tertiary lid is separated from the secondary lid over the entire surface via the first space,
The tertiary lid has a cover portion that covers at least a part of a side surface of the trunk body on an outer peripheral portion, and the cover portion is separated from the side surface of the trunk body over the entire surface via a second space. And
The distance between the primary lid and the secondary lid via the lower space is longer than the distance between the tertiary lid and the secondary lid via the first space, and the second space. A radioactive substance storage container that is longer than a distance between the cover part and a side surface of the trunk main body via a buffer, and a buffer part that absorbs an impact of the secondary lid is provided in the lower space . A transport cushion covering the outer side of the trunk lid and the trunk lid for mounting instead of the tertiary lid can be attached to and detached from the trunk body.
A plurality of screw holes are formed along the circumferential direction on the outer side of the opening in the trunk body, and screw portions of a plurality of bolts pass through the tertiary lid and are respectively tightened into the screw holes to thereby form the tertiary lid. Attached to the trunk body,
A plurality of bolt threaded portions can be attached to the trunk body by passing through the transportation tertiary lid and being tightened to a part of the screw holes, respectively.
The transport buffer can be attached to the trunk body by threading portions of a plurality of bolts passing through the transport buffer and tightening each other part of the screw hole.
The radioactive substance storage container according to claim 1 . A transport cushion covering the outer side of the tertiary lid and the trunk body can be attached to and detached from the trunk body.
The radioactive substance storage container according to claim 1. A plurality of screw holes are formed along the circumferential direction outside the opening in the trunk body,
The threaded part of a plurality of bolts penetrates the tertiary lid and is respectively tightened to a part of the screw hole so that the tertiary lid can be attached to the trunk body,
The transport buffer can be attached to the trunk body by screwing the threaded portions of a plurality of bolts through the transport buffer and tightening each other part of the screw hole.
The radioactive substance storage container according to claim 3 . The tertiary lid is disc-shaped, and an opening is formed at the center.
The radioactive substance storage container according to any one of claims 1 to 4 . The tertiary lid is a hollow member.
The radioactive substance storage container according to any one of claims 1 to 5 . The tertiary lid has a heat insulating part inside,
The radioactive substance storage container according to claim 6 . An inclined surface that is tapered toward the opening side in the longitudinal direction of the trunk body is provided on the outer peripheral surface of the cover portion.
The radioactive substance storage container according to any one of claims 1 to 7 . The tertiary lid has a reinforcing member that connects a plurality of plate-like members extending toward the outside of the tertiary lid.
The radioactive substance storage container according to any one of claims 1 to 8 . The cover part is provided with a holding part at a tip located on the other end side of the trunk body from the secondary lid,
The holding portion extends from one end portion to the other end portion along the outer periphery of the trunk main body, and the one end portion faces the other end portion, By fixing one end and the other end with a bolt, the outer periphery of the trunk body is tightened.
The radioactive substance storage container according to claim 1 . A trunnion is provided on a side surface of the trunk body,
The cover portion is provided with a fixing portion at a tip located on the other end side of the trunk body from the secondary lid,
The fixing portion includes a collar portion, and the third lid is fixed to the trunnion by engaging the collar portion and the trunnion.
The radioactive substance storage container according to claim 1 . The tertiary lid is filled with foam metal inside.
The radioactive substance storage container according to any one of claims 1 to 11 . A radioactive substance is stored in a radioactive substance storage container having a trunk body which is a cylindrical member having an opening at one end,
A primary lid is attached to the opening,
A secondary lid is attached to the outside of the primary lid in the opening,
A third lid that protects the secondary lid from external impact is attached to the outside of the secondary lid in the opening, and the radioactive substance is stored.
Remove the tertiary lid, attach a transport tertiary lid to the outside of the secondary lid in the opening,
A transport cushion covering the outside of the trunk body is attached to the trunk body to transport the radioactive substance,
The secondary lid is separated from the primary lid over the entire surface via a lower space,
The tertiary lid is separated from the secondary lid over the entire surface via the first space,
The tertiary lid has a cover portion that covers at least a part of a side surface of the trunk body on an outer peripheral portion, and the cover portion is separated from the side surface of the trunk body over the entire surface via a second space. And
The distance between the primary lid and the secondary lid via the lower space is longer than the distance between the tertiary lid and the secondary lid via the first space, and the second space. Longer than the distance between the cover portion and the side surface of the trunk body via the buffer space is provided in the lower space to absorb the impact of the secondary lid,
Methods for storing and transporting radioactive materials. A plurality of screw holes are formed on the outer side of the opening in the trunk body along the circumferential direction, and screw portions of a plurality of bolts pass through the tertiary lid and are respectively tightened into the screw holes to thereby fix the tertiary lid. Attached to the trunk body,
A plurality of bolt thread portions are passed through the transportation tertiary lid and tightened to a part of the screw holes to attach the transportation tertiary lid to the trunk body,
A plurality of bolt thread portions are passed through the transportation buffer body and are respectively fastened to other parts of the thread portion to attach the transportation buffer body to the trunk body.
A method for storing and transporting a radioactive substance according to claim 13 .

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