JP6053394B2 - Radioactive material storage container - Google Patents

Description

  The present invention relates to a radioactive substance storage container that stores, transports, and stores radioactive waste, and more particularly, to a trunnion mounting structure that is fixed to an outer peripheral portion for lifting the radioactive substance storage container.

  Radioactive waste generated in a nuclear power plant nuclear reactor or the like is stored in a radioactive material storage container, transported to a storage facility or a reprocessing facility, and stored or reprocessed. Such a radioactive substance storage container is composed of, for example, a cylindrical body having a bottom with an open top and a lid fixed to the upper part of the trunk, and is hung on the outer periphery of the trunk. A number of trunnions are installed. Since the radioactive substance storage container is transported not only in a standing state but also in a lying state, two trunnions are installed at the upper part of the trunk and two or four trunnions.

  The radioactive waste is stored in a radioactive substance storage container, transported to a storage facility or a reprocessing facility by a ship or a vehicle, and stored or reprocessed for a predetermined number of years in this facility. In this conveyance and handling, the radioactive substance storage container is suspended and transferred via a trunnion by a container transfer crane or the like.

  By the way, as for this radioactive substance storage container, the several trunnion is being fixed to the outer peripheral part of the trunk | drum with several bolts. That is, the trunnion is formed by integrally forming a seat portion having a disc flange shape that is seated and fixed on the body portion, and a latching portion having a columnar shape for coupling with the suspension. A plurality of mounting holes are formed in the outer periphery of the. On the other hand, the body portion is formed with a mounting recess in which the seating portion is fitted at a predetermined position on the outer peripheral portion, and a plurality of screw holes into which the bolts are screwed. Therefore, the trunnion is fixed to the trunk portion by fitting the seating portion into the mounting recess of the trunk portion, and in this state, a plurality of bolts pass through the respective mounting holes and are screwed into the screw holes and fastened. Yes.

  Such a radioactive substance storage container is, for example, described in Patent Document 1 below as a cask for storing a spent fuel assembly.

Japanese Patent No. 3150674

  Since the radioactive substance storage container described above stores radioactive waste therein, a neutron shield is provided on the outer periphery of the trunk portion in order to prevent leakage of neutrons (neutron rays) to the outside. However, it is difficult for the trunk portion to provide a neutron shield on the position where the trunnion is fixed, particularly on the seat portion having a disk flange shape through which a plurality of bolts penetrate. Therefore, the radioactive substance storage container is required to improve the performance of the neutron shielding function. In Patent Document 1 described above, a neutron shield is provided on the outer peripheral side of the seating portion of the trunnion, but it is difficult for the bolt to pass through the neutron shield and fasten to the trunk, and the neutron shield. There is a possibility that the mounting structure becomes complicated, the number of parts increases, and the manufacturing cost increases.

  Further, the radioactive substance storage container is generally provided with two trunnions on the upper part and two or four trunnions on the lower part. When fixing a trunnion to the body, a plurality of (for example, 12) bolts are required. To fix four trunnions to the body, a large number (for example, 48) of bolts are required. Not only will costs increase, but work costs will also increase. On the other hand, the same number of fastening holes formed in the body portion is required, which also increases the manufacturing cost.

  The present invention solves the above-described problems, and an object of the present invention is to provide a radioactive substance storage container that can improve the neutron shielding function and simplify the trunnion structure and reduce the cost.

  In order to achieve the above object, the radioactive substance storage container of the present invention has a cylindrical shape in which an opening is formed on one side and a closed part is formed on the other, and a trunk part capable of storing the radioactive substance therein, A lid that can be attached to the barrel so as to close the opening; a latching portion for suspension; and a first threaded portion that is screwed into a predetermined position on the outer periphery of the barrel. And a plurality of trunnions.

  Therefore, the trunnion is screwed and fastened to a predetermined position on the outer peripheral portion of the trunk portion by the first screw portion, so that it is not necessary to provide a flange portion through which a plurality of bolts penetrate, and the vicinity of the periphery A neutron shielding body can be arranged, the neutron shielding function can be improved, and the trunnion can be simplified, so that the cost can be reduced.

  In the radioactive substance storage container of the present invention, the trunnion is characterized in that a tool locking hole capable of locking a rotation tool is provided at the tip of the hooking portion.

  Therefore, by locking the rotating tool in the tool locking hole and rotating, the trunnion can be rotated and the first threaded portion can be screwed into the body portion, and the retaining portion can be engaged with the rotating tool or the like. It is not necessary to rotate the trunnion by gripping the outside, and damage to the latching portion can be prevented.

  In the radioactive substance storage container of the present invention, the body portion has a cylindrical shape, and a protruding portion that protrudes outward is provided at a predetermined position on the outer peripheral portion, and a recessed portion that is recessed from the outside is provided with respect to the protruding portion. The second screw portion into which the first screw portion is screwed is provided on the inner peripheral portion of the concave portion.

  Therefore, by providing the second screw portion in the recess of the protruding portion that protrudes outward from the outer peripheral portion of the body portion, it is possible to ensure a sufficient length of the second screw portion into which the first screw portion is screwed. It is possible to secure a sufficient fastening force of the trunnion to the trunk portion.

  In the radioactive substance storage container of the present invention, the trunnion has a first neutron shield disposed therein, while the trunk has a second neutron shield disposed on the outer periphery thereof, and the trunnion and the second neutron A predetermined gap is provided between the shield and the shield.

  Therefore, by arranging the first neutron shield inside the trunnion and providing the second neutron shield with a predetermined clearance from the trunnion in the trunk, the neutron shielding function can be improved and the trunnion with respect to the trunk is improved. It is possible to improve the wearability and the hookability of the suspension member with respect to the trunnion.

  In the radioactive substance storage container of the present invention, the trunnion has a cylindrical shape, and the second neutron shield is provided with a circular notch that is larger than the outer diameter of the trunnion at a position corresponding to the trunnion. It is said.

  Therefore, the second neutron shield can be disposed up to the vicinity of the trunnion, and the neutron shielding function can be improved.

  In the radioactive substance storage container of the present invention, the trunnion is provided with a larger-diameter portion that is larger than the outer diameter of the hook portion, and the first screw portion is formed on the outer peripheral portion of the larger-diameter portion, and the large-diameter portion The outer position of the trunk portion and the outer position of the second neutron shield in the trunk portion are set at substantially the same position.

  Therefore, the appearance quality can be improved by reducing the stepped portion on the outer peripheral surface of the body portion, and the handleability at the time of transportation or storage can be improved.

  In the radioactive substance storage container of the present invention, the trunk portion is provided with a cylindrical ring portion at a predetermined position on the outer peripheral portion, and the second screw portion is screwed into the inner peripheral portion of the ring portion. A screw part is provided, and the second neutron shield is extended to the ring part.

  Therefore, the second neutron shield can be disposed up to the vicinity of the trunnion, and the neutron shielding function can be improved.

  In the radioactive substance storage container of the present invention, the first screw portion is a tapered screw having a tapered tip portion.

  Therefore, the trunnion can be firmly fixed to the trunk portion, and the stress of the thread portion when a load acts on the trunnion can be reduced.

  According to the radioactive substance storage container of the present invention, a plurality of trunnions having a trunk portion, a lid portion, a hooking portion for suspension, and a first screw portion screwed into a predetermined position in the outer peripheral portion of the trunk portion. Therefore, the neutron shielding function can be improved, the trunnion can be simplified, and the cost can be reduced.

FIG. 1 is a cross-sectional view illustrating a trunnion mounting portion in a cask as a radioactive substance storage container according to Embodiment 1 of the present invention. FIG. 2 is a front view illustrating a trunnion mounting portion in the cask of the first embodiment. FIG. 3 is a partial cross-sectional schematic view of the cask of the first embodiment. FIG. 4 is a horizontal sectional view of the cask of the first embodiment. FIG. 5 is a schematic diagram illustrating a storage facility for storing the cask of the first embodiment. FIG. 6 is a cross-sectional view showing a trunnion mounting portion in a cask as a radioactive substance storage container according to Embodiment 2 of the present invention.

  Exemplary embodiments of a radioactive substance storage container according to the present invention will be described below in detail with reference to the accompanying drawings. In addition, this invention is not limited by this Example, Moreover, when there exists multiple Example, what comprises combining each Example is also included.

  1 is a cross-sectional view illustrating a trunnion mounting portion in a cask as a radioactive substance storage container according to Embodiment 1 of the present invention, FIG. 2 is a front view illustrating a trunnion mounting portion in a cask of Embodiment 1, and FIG. 4 is a partial cross-sectional schematic view of the cask of the first embodiment, FIG. 4 is a horizontal cross-sectional view of the cask of the first embodiment, and FIG. 5 is a schematic view showing a storage facility for storing the cask of the first embodiment.

  In the first embodiment, as shown in FIGS. 3 and 4, the cask 11 as a radioactive substance storage container includes a trunk portion 12 and a lid portion 13. 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 that matches the outer peripheral shape of the basket 25. And the trunk | drum main body 21 has the bottom part 23 couple | bonded by welding to this lower part, and this trunk | drum main body 21 and the bottom part 23 are forged goods made from carbon steel which has a gamma ray shielding function, but instead of carbon steel Stainless steel can also be used. Also, cast products such as spheroidal graphite cast iron and carbon steel cast steel can be used.

  The basket 25 provided inside the cask 11 is composed of a plurality of square pipes constituting a cell 26 for storing a spent fuel assembly (not shown). This square pipe is made of an aluminum composite material or an aluminum alloy obtained by adding boron or boron compound powder having neutron absorption performance to aluminum or aluminum alloy powder. In addition to boron, gadolinium can be used as the neutron absorber.

  The body portion 12 is provided with an outer cylinder 27 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 27. A plurality of copper heat transfer fins 28 are welded at equal intervals in the circumferential direction. The body 12 is a resin (second neutron shield) containing boron or a boron compound which is a polymer material containing a lot of hydrogen and has a neutron shielding function in the space between the body 21 and the outer cylinder 27. ) 29 is injected through a pipe or the like (not shown) in a fluidized state and solidified. In this case, it is preferable that the heat transfer fins 28 are provided at a high density in a portion having a large amount of heat in order to uniformly dissipate heat.

  The body 12 is connected to a bottom plate 36 with a plurality of connecting plates 30 with a predetermined gap below the bottom 23, and a resin (neutron shield) is formed in a space between the bottom 23 and the bottom plate 36. 37 is provided.

  The lid 13 that closes the opening 22 of the trunk body 21 in the trunk 12 includes a primary lid 31 and a secondary lid 32. The primary lid portion 31 has a disk shape made of stainless steel or carbon steel that shields γ rays. The secondary lid portion 32 also has a disk shape made of stainless steel or carbon steel, and a resin (neutron shield) 33 is sealed on the upper surface thereof. The primary lid portion 31 and the secondary lid portion 32 are attached to the upper end portion of the trunk body 21 with a bolt 34 made of stainless steel or carbon steel. In this case, metal gaskets (not shown) are interposed between the primary lid portion 31 and the secondary lid portion 32 and the trunk main body 21 to ensure the internal sealing performance. Further, an auxiliary shield 36 enclosing the resin 35 is provided around the lid portion 13.

  Moreover, the trunk | drum 12 is provided with the trunnion 41 for lifting the cask 11 in two places of the upper part of the trunk | drum main body 21, and two places of the lower part. In this case, the trunnions 41 are provided at equal intervals in the circumferential direction on the upper portion of the trunk body 21 and at equal intervals in the circumferential direction on the lower portion of the trunk body 21. The cask 11 accommodates the spent fuel assembly therein and is then transported to the storage facility (or reprocessing facility). When the cask 11 is transported, the auxiliary shield attached to the upper end of the trunk 12 is used. The body 36 is removed, and shock absorbers (not shown) are attached to the upper end portion and the lower end portion of the cask 11. This shock absorber has a structure in which a shock absorber such as wood is incorporated in a housing made of stainless steel. Further, after the cask 11 is carried into the storage facility, the buffer body is removed and stored in an upright state using a mounting table 107 described later.

  As shown in FIG. 5, the storage facility 101 is entirely composed of concrete walls, and includes an installation floor 102, a ceiling wall 103, and a plurality of side walls 104. The installation floor 102 is provided with a ventilation tower 106 having a large number of air inlets 105 formed on both sides thereof. In the storage facility 101, the cask 11 is arranged on each installation base 107 fixed to the installation floor 102, and a plurality of predetermined intervals are arranged in the horizontal direction. As described above, each cask 11 contains a spent fuel assembly. Further, the storage facility 101 is provided with a loading pit 109 having a loading gate 108 on one side, and the cask 11 is carried into the storage facility 101 from the loading pit 109 by a transport vehicle. In the storage facility 101, a cask transfer crane 110 is movably provided at an upper portion, and the cask 11 carried into the carry-in pit 109 is transferred by the cask transfer crane 110 and is arranged at a predetermined position. .

  As described above, the cask 11 according to the first embodiment configured as described above has a plurality (four in this embodiment) for lifting the cask 11 at a predetermined position on the outer peripheral portion of the trunk portion 12. The trunnion 41 is fixed. In the first embodiment, each trunnion 41 is fixed by screwing without using a plurality of bolts for mounting.

  Hereinafter, although the trunnion 41 fixed to the trunk | drum 12 is demonstrated in detail, the one trunnion 41 fixed to the outer peripheral upper end part of the trunk | drum main body 21 in the trunk | drum 12 is demonstrated here. The trunnion 41 fixed to the outer peripheral lower end of the trunk body 21 in the trunk section 12 has the same configuration.

  As shown in FIGS. 1 and 2, the trunnion 41 has a cylindrical shape, a hanging latching portion 42 that locks a wire, a rope, an alloy, and the like, and a trunk body 21 that constitutes the trunk portion 12. And a first screw portion 43 that is screwed into a predetermined position on the outer peripheral portion of the first screw portion 43.

  That is, the trunnion 41 has a cylindrical shape in which a small-diameter portion 51, a medium-diameter portion 52, and a large-diameter portion 53 that form a cylindrical shape are integrally formed. As for the small diameter part 51, the outer peripheral part functions as the latching | locking part 42, and the flange part 51a which makes a disk shape in the front-end | tip part is integrally formed. The medium diameter portion 52 has an outer diameter set larger than the outer diameter of the small diameter portion 51, and an end surface portion 52 a having a ring shape is formed to face the flange portion 51 a of the small diameter portion 51 with the latching portion 42 interposed therebetween. . That is, the trunnion 41 has a structure in which a wire or the like locked to the hooking portion 42 (the outer peripheral portion of the small diameter portion 51) is maintained between the flange portion 51a and the end surface portion 52a, and is difficult to come off.

  Further, the small diameter portion 51 is provided with a tool locking hole 51c in which a rotation tool (not shown) can be locked at the distal end portion 51b. The tool locking hole 51c is, for example, a hexagonal hole. When the tip of the rotating tool (hexagonal portion) is locked from the outside, the tool for rotation is rotated to rotate the tool engaging tool. The trunnion 41 can be rotated through the blind hole 51c. The small-diameter portion 51 is formed so that the working space portion 51d communicates with the back side of the tool locking hole 51c. When the rotary tool is rotated, the frictional resistance between the rotary tool and the trunnion 41 is reduced. I try to reduce it. Although the tool locking hole 51c is a hexagonal hole, it may be a square hole or a slit hole, and may be any shape as long as the rotation tool can be locked and the trunnion 41 can be rotated. .

  The large-diameter portion 53 has an outer diameter set larger than the outer diameter of the medium-diameter portion 52, an end surface portion 53a having a ring shape is formed, and a first screw portion 43 is formed on the base end side of the outer peripheral portion. ing.

  Further, the trunnion 41 is formed of a cylindrical storage space portion 53c on the end surface portion 53b of the base end portion on the large diameter portion 53 side, and the storage space portion 53c is a polymer material containing a large amount of hydrogen. A resin (first neutron shield) 54 containing boron or a boron compound having a neutron shielding function is injected and solidified through a pipe or the like (not shown) in a flowing state. The storage space 53c is closed by fixing the lid member 55 by welding or the like in a state where the resin 54 is stored.

  On the other hand, the trunk body 21 constituting the trunk portion 12 is provided with a protruding portion 61 that protrudes radially outward at the upper end portion of the outer peripheral portion, and a cylinder that is recessed from the radially outer side with respect to the protruding portion 61. By providing the concave portion 62 having a shape, a ring portion 63 having a cylindrical shape is provided. A second threaded portion 64 is provided in which the first threaded portion 43 of the trunnion 41 is screwed into the inner circumferential portion of the recess 62, that is, the inner circumferential portion of the ring portion 63. In this case, by setting the protruding portion 61 to an appropriate protruding height, the length of the second screw portion 64 and the first screw length can be made equal, and an appropriate tightening force can be obtained. Further, by setting the width of the projection 61 to an appropriate value, the projection 61 can obtain rigidity as a tightened body, and the length of the second screw portion 64 and the first screw length can be made equal. And an appropriate tightening force can be obtained.

  In the ring portion 63, the height of the inner peripheral surface (the radial direction length in the trunk body 21), that is, the depth is set larger than the height of the outer peripheral surface (the radial direction length in the trunk body 21). ing. As described above, the barrel main body 21 is provided with an outer cylinder 27 with a predetermined gap on the outer peripheral side, and a resin (first resin) between the outer peripheral surface of the barrel main body 21 and the inner peripheral surface of the outer cylinder 27. 2 neutron shield) 29 is provided.

  The trunnion 41 is fastened to the trunk portion 12 by the first screw portion 43 being screwed into the second screw portion 64 formed in the ring portion 63 of the trunk body 21. In this case, the trunnion 41 is fixed at a position where the end surface portion 53 b contacts the bottom surface of the recess 62 of the trunk body 21. In the state where the trunnion 41 is fastened to the trunk body 21 in this way, the resin 29 (outer cylinder 27) is arranged to extend to the vicinity of the outer peripheral surface of the ring portion 63, but with the outer peripheral surface of the trunnion 41 A predetermined gap S is provided between them.

  That is, the resin 29 is provided at a position corresponding to the trunnion 41 with a circular notch 65 larger than the outer diameter of the trunnion 41, so that the resin 29 is located between the outer peripheral surface of the trunnion 41 and the resin 29 (outer cylinder 27). A predetermined gap S is secured. By providing the predetermined gap S, the trunnion 41 can be screwed to the main body barrel 12.

  Further, a radially outward position in the trunk portion 12 of the resin 29 (outer cylinder 27) disposed in the trunk body 21 and a radially outward position in the trunk portion 12 of the large diameter portion 53 formed in the trunnion 41. Are set at approximately the same position. The resin 29 (outer cylinder 27) is extended to the end surface portion 63 a of the ring portion 63, so that a predetermined gap S is provided between the resin 29 and the outer peripheral surface of the trunnion 41.

  That is, since the cask 11 is provided with the trunnion 41 after the resin 29 (outer cylinder 27) is provided on the trunk body 21, the cask 11 is interposed between the trunnion 41 and the resin 29 (outer cylinder 27) after fastening. By setting the dimensions of the trunnion 41 and the resin 29 (outer cylinder 27) so that the predetermined gap S is formed, the trunnion 41 can be easily attached to the trunk body 21.

  As described above, the cask 11 of the first embodiment has a cylindrical shape in which the opening portion 22 is formed on one side and the bottom portion 23 is formed on the other side. A lid portion 13 that can be attached to the trunk portion 12 so as to close the portion 22; a hanging latch portion 42; and a first screw portion 43 that is screwed into a predetermined position on the outer peripheral portion of the trunk portion 12. A plurality of trunnions 41 having

  Accordingly, the four trunnions 41 are screwed into a predetermined position on the outer peripheral portion of the trunk body 12 by the first screw portion 43 and fastened to provide a mounting flange and a mounting hole through which a plurality of bolts pass. It is not necessary, and the resin 29 (outer cylinder 27) can be arranged up to the vicinity of the periphery, and the neutron shielding function can be improved. Moreover, since the structure of the trunnion 41 is simplified and a plurality of bolts are not required, the manufacturing cost of the cask 11 can be reduced.

  In the cask 11 of the first embodiment, a tool locking hole 51c capable of locking a rotating tool is provided at the tip of the latching portion 42 of the trunnion 41. Accordingly, the rotation tool is inserted and locked in the tool locking hole 51c, and the rotation tool is rotated, whereby the trunnion 41 is rotated and the first screw portion 43 is screwed into the trunk body 21. Thus, a rotating tool for gripping the outside of the latching portion 42 is not necessary, and it is not necessary to rotate the trunnion 41 with this rotating tool, and damage to the latching portion 42 can be prevented.

  In the cask 11 of the first embodiment, the trunk body 21 has a cylindrical shape, and a protruding portion 61 that protrudes outward is provided at a predetermined position on the outer peripheral portion, and a concave portion 62 that is recessed from the outside is provided on the protruding portion 61. A second screw portion 64 into which the first screw portion 43 is screwed is provided on the inner peripheral portion of the recess 62. Therefore, by providing the second screw portion 64 in the recess 62 of the protruding portion 61 that protrudes outward from the outer peripheral portion of the trunk body 21, a sufficient length of the second screw portion 64 to which the first screw portion 43 is screwed. Therefore, a sufficient fastening force of the trunnion 41 to the trunk body 21 can be ensured.

  In the cask 11 of the first embodiment, the resin 54 is disposed inside the trunnion 41, while the resin 29 is disposed on the outer peripheral portion of the trunk body 21, and a predetermined gap S is provided between the trunnion 41 and the resin 29. Therefore, the neutron shielding function can be improved by arranging the resin 54 inside the trunnion 41 and providing the resin 29 with the predetermined clearance S from the trunnion 41 in the trunk body 21. Further, by providing the predetermined gap S between the trunnion 41 and the resin 29, the trunnion 41 can be easily mounted on the trunk body 21 to which the resin 29 is attached, and the mounting performance of the trunnion 41 is improved. be able to. Furthermore, the hanging member can be easily hooked to the trunnion 41, and the hooking property of the hanging member can be improved.

  In the cask 11 of the first embodiment, the trunnion 41 has a cylindrical shape, and a circular notch 65 larger than the outer diameter of the trunnion 41 is provided at a position corresponding to the trunnion 41 in the resin 54. Therefore, the resin 54 can be disposed up to the vicinity of the trunnion 41, and the neutron shielding function can be improved.

  In the cask 11 of the first embodiment, the trunnion 41 is provided with a large-diameter portion 53 larger than the outer diameter of the latching portion 42, and the first screw portion 43 is formed on the outer peripheral portion of the large-diameter portion 53. The outer position of the trunk body 21 and the outer position of the resin 29 in the trunk body 21 are set at substantially the same position. Therefore, the appearance quality can be improved by reducing the stepped portion on the outer peripheral surface of the body 12, and the handleability at the time of transportation or storage can be improved.

  In the cask 11 of the first embodiment, a ring portion 63 having a cylindrical shape is provided at a predetermined position in the outer peripheral portion of the trunk portion 12, and a second screw in which the first screw portion 43 is screwed into the inner peripheral portion of the ring portion 63. A portion 64 is provided, and the resin 29 extends to the ring portion 63. Accordingly, the resin 29 can be disposed up to the vicinity of the trunnion 41, and the neutron shielding function can be improved.

  FIG. 6 is a cross-sectional view showing a trunnion mounting portion in a cask as a radioactive substance storage container according to Embodiment 2 of the present invention. In addition, the same code | symbol is attached | subjected to the member which has the function similar to the Example mentioned above, and detailed description is abbreviate | omitted.

  In the second embodiment, as shown in FIG. 6, the trunnion 71 has a cylindrical shape, and constitutes a trunk portion 12 and a hooking portion 42 for suspending a wire, a rope, an alloy, and the like. And a first screw portion 72 that is screwed into a predetermined position on the outer peripheral portion of the trunk body 21.

  That is, the trunnion 71 has a cylindrical shape in which a small-diameter portion 51, a medium-diameter portion 52, and a large-diameter portion 73 that form a cylindrical shape are integrally formed. The small diameter portion 51 and the medium diameter portion 52 have substantially the same configuration as the trunnion 41 of the first embodiment.

  The large-diameter portion 73 has an outer diameter set larger than the outer diameter of the medium-diameter portion 52, an end surface portion 73a having a ring shape is formed, and an outer peripheral portion is tapered toward the base end portion side. The 1st thread part 72 is formed in the base end part side. That is, in the trunnion 71 of the second embodiment, the first screw portion 72 is a taper screw. In the trunnion 71, a cylindrical storage space portion 73c is formed on the end surface portion 73b of the base end portion on the large diameter portion 73 side, and a resin (first neutron shield) 54 is formed in the storage space portion 73c. It is mounted and closed by the lid member 55.

  On the other hand, the trunk main body 21 constituting the trunk portion 12 is provided with a protruding portion 81 protruding radially outward at the upper end portion of the outer peripheral portion, and a cylinder recessed from the radially outer side with respect to the protruding portion 81. By providing the concave portion 82 having a shape, a ring portion 83 having a cylindrical shape is provided. A second screw portion 84 is provided in which the first screw portion 72 of the trunnion 71 is screwed into the inner peripheral portion of the recess 82, that is, the inner peripheral portion of the ring portion 83. The second screw portion 84 has a tapered shape that matches the tapered shape of the first screw portion 72.

  As described above, the cask 11 of the second embodiment has a cylindrical shape in which the opening portion 22 is formed on one side and the bottom portion 23 is formed on the other side. A lid portion 13 that can be attached to the body portion 12 so as to close the portion 22; a hooking portion 42 for suspension; and a first screw portion 72 that is screwed into a predetermined position on the outer peripheral portion of the body portion 12; And a plurality of trunnions 71 having.

  Therefore, the trunnion 71 needs to be provided with a mounting flange and a mounting hole through which a plurality of bolts pass by being screwed and fastened to a predetermined position on the outer peripheral portion of the trunk body 21 by the first screw portion 72. Therefore, the resin 29 (outer cylinder 27) can be disposed up to the vicinity of the periphery, and the neutron shielding function can be improved. Moreover, since the structure of the trunnion 71 is simplified and a plurality of bolts are not required, the manufacturing cost of the cask 11 can be reduced.

  In the cask 11 of the second embodiment, the first screw portion 72 of the trunnion 71 is a tapered screw with a tapered tip. Accordingly, the trunnion 71 can be firmly fixed to the trunk portion 12, and the stress of the threaded portion when a load is applied to the trunnion 71 can be reduced.

  In the embodiment described above, the shape of the trunnion is not limited to the shape of the embodiment described above, and is not limited to the columnar shape but may be a prismatic shape. Further, the number of trunnions with respect to the trunk portion 12 is not limited to the upper two places and the lower two places, and may be four places.

11 Cask (radioactive substance storage container)
12 trunk part 13 lid part 21 trunk body 22 opening part 23 bottom part (blocking part)
27 Outer cylinder 29 Resin (second neutron shield)
41, 71 trunnion 42 latching portion 43, 72 first screw portion 51 small diameter portion 52 medium diameter portion 53, 73 large diameter portion 54 resin (first neutron shield)
61, 81 Protruding part 62, 82 Recessed part 63, 83 Ring part 64, 84 Second screw part

Claims (9)

A barrel portion that is formed in a cylindrical shape in which an opening portion is formed on one side and a blocking portion is formed on the other side, and in which a radioactive substance can be stored,
A lid that can be attached to the trunk so as to close the opening;
A plurality of trunnions having a hanging latching portion and a first screw portion screwed into a predetermined position on the outer peripheral portion of the body portion;
Bei to give a,
The trunnion is provided with a tool locking hole capable of locking a rotating tool at the tip of the hooking portion,
The tool locking hole has a working space formed on the back side.
A radioactive substance storage container. The trunk portion has a cylindrical shape, and is provided with a protruding portion that protrudes outward at a predetermined position on the outer peripheral portion, and is provided with a concave portion that is recessed from the outside with respect to the protruding portion. The radioactive substance storage container according to claim 1 , further comprising a second screw portion into which the first screw portion is screwed.   The trunnion has a first neutron shield disposed therein, while the body has a second neutron shield disposed on the outer periphery thereof, and a predetermined gap is provided between the trunnion and the second neutron shield. The radioactive substance storage container according to claim 1, wherein the radioactive substance storage container is provided. The radioactive form according to claim 3 , wherein the trunnion has a cylindrical shape, and the second neutron shield is provided with a circular notch that is larger than the outer diameter of the trunnion at a position corresponding to the trunnion. Substance storage container. The trunnion is provided with a large-diameter portion that is larger than the outer diameter of the latching portion, the first screw portion is formed on an outer peripheral portion of the large-diameter portion, and an outer position of the trunk portion of the large-diameter portion The radioactive substance storage container according to claim 3 or 4 , wherein an outer position of the body portion of the second neutron shield is set at substantially the same position. The barrel portion is provided with a cylindrical ring portion at a predetermined position on the outer peripheral portion, and a second screw portion is provided on the inner peripheral portion of the ring portion to which the first screw portion is screwed. The radioactive substance storage container according to any one of claims 3 to 5 , wherein the neutron shield extends to the ring portion.   The radioactive substance storage container according to claim 1, wherein the first screw portion is a taper screw having a tapered tip portion.   The trunnion is provided with a large-diameter portion larger than the outer diameter of the latching portion, the first screw portion is formed on the outer peripheral portion of the large-diameter portion, and the large-diameter portion has the same diameter along the axial direction. The radioactive substance storage container according to claim 1, wherein the container is a radioactive substance storage container.   The trunnion has a first neutron shield disposed therein, while the body has a second neutron shield disposed on the outer periphery and a cylindrical ring portion at a predetermined position on the outer periphery. The radioactive substance storage container according to claim 1, wherein the second neutron shield is provided to extend to an end face of the ring portion.

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