JP6165028B2 - Radioactive substance storage container support stand - Google Patents

Description

  The present invention relates to a radioactive substance storage container support frame that supports a radioactive substance storage container that stores radioactive waste.

  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. In such a radioactive substance storage container, a plurality of trunnions are formed so as to protrude from the outer side of the trunk portion serving as a main body of the container, and supported by a support frame via the trunnions. The radioactive substance storage container is transported with a support frame fixed to a trailer or the like.

  Such a radioactive substance storage container support gantry includes a base and a support portion that stands on the upper side of the base and clamps the trunnion. For example, a wet transportation container described in Patent Document 1 Transportation platforms are known. In addition, the transportation platform of the wet transportation container described in Patent Document 1 is provided with a cylinder device that raises and lowers the clamp of the support portion itself or the upper end portion on at least one of the front and rear support portions. In order to change the inclination of the supported wet transportation container by alternately raising and lowering the front and rear support parts, and promoting the flow in the axial direction of the water contained therein, the wet transportation It has the function of enhancing the heat transfer performance inside the container and promoting the heat removal function.

JP 7-325191 A

  By the way, when storing the radioactive substance storage container, for example, after being carried into the storage building by a trailer or the like, the whole support frame is lifted and unloaded, but when the whole support frame is dropped in the lifted state, There is a possibility that the clamp of the support part breaks and comes off or the trunnion breaks. In such a case, the sealed portion of the lid of the radioactive substance storage container, the container body, or the stored radioactive substance may be damaged.

  The present invention solves the above-described problems, and supports a radioactive substance storage container that can relieve the impact force on the radioactive substance storage container and the support portion when falling in a state of supporting the radioactive substance storage container. The purpose is to provide a platform.

  In order to achieve the above object, a radioactive substance storage container support frame according to the present invention includes a base placed on a floor surface, and a radioactive substance storage container standing on the base and storing a radioactive substance. A radioactive substance storage container support gantry having a supporting part for supporting, wherein the radioactive substance storage container support frame is provided so as to be able to support a load of the radioactive substance storage container, and further includes a buffer member that is plastically deformed by an external force and absorbs an impact. .

  According to this radioactive substance storage container support frame, when there is an event of falling while supporting the radioactive substance storage container, the buffer member is plastically deformed by the external force due to the fall and absorbs the shock, thereby storing the radioactive substance. Since the impact force on the container and the support part is reduced, it is possible to prevent a situation where the sealed part, the container body, and the stored radioactive substance in the radioactive substance storage container are damaged.

  In the radioactive substance storage container support frame of the present invention, the buffer member is made of a ductile material.

  According to the radioactive substance storage container support frame, the ductile material has a property of being stretched plastically and mainly includes a metal material. For example, when a tensile stress is applied to a metal material, it is stretched plastically and causes plastic deformation. That is, the ductile material is plastically deformed by an external force and absorbs an impact. Therefore, the impact force applied to the radioactive substance storage container and the support portion can be reduced by the buffer member made of the ductile material.

  Further, in the radioactive substance storage container support frame of the present invention, the buffer member is disposed along the cylindrical axial direction in an external force application direction in which the ductile material is formed in a cylindrical shape and can be assumed. To do.

  According to this radioactive substance storage container support gantry, in the cylindrical cushioning member, the stress on the cylinder when the weight of the cask and the support gantry x α (external force) acts is less than the stress that buckles, It is possible to ensure the strength of the support frame during normal operation. And in the event of a fall, an impact force can be absorbed by deforming a cylinder shape exceeding a buckling stress by the impact force which generate | occur | produces.

  In the radioactive substance storage container support frame of the present invention, the buffer member is characterized in that the cylindrical interior is filled with foam.

  According to this radioactive substance storage container support gantry, the above-described buckling stress is raised by filling the cylindrical interior with the foam, so that the impact force absorption performance is increased. For this reason, the effect of relieving the impact force to a radioactive substance storage container and a support part can be acquired notably at the time of fall. Further, since the impact force absorption performance is increased, the cylindrical length can be shortened to reduce the size of the buffer member.

  In the radioactive substance storage container support frame of the present invention, the buffer member is formed by covering a material having a predetermined compression characteristic with a covering material that can be plastically deformed.

  According to this radioactive substance storage container support frame, even such a buffer member can be plastically deformed and absorbed by an external force due to dropping, and can absorb the impact on the radioactive substance storage container and the support part. For this reason, it is possible to prevent the sealed portion in the radioactive substance storage container, the container body, and the stored radioactive substance from being damaged.

  In the radioactive substance storage container support frame of the present invention, the buffer member is characterized in that an orifice is provided in an opening of a deformable container filled with a fluid.

  According to this radioactive substance storage container support frame, even with such a buffer member, it is possible to absorb the shock by plastic deformation due to the external force due to dropping, and the shock absorbing characteristics of the buffer member due to the provision of the orifice To reduce the impact force on the radioactive substance storage container and the support part, so that the sealed part of the radioactive substance storage container, the container body and the stored radioactive substance can be prevented from being damaged. it can.

  In the radioactive substance storage container support frame of the present invention, the buffer member is formed by filling a deformable container with sol or gel.

  According to this radioactive substance storage container support frame, even such a buffer member can be plastically deformed and absorbed by an external force due to dropping, and can absorb the impact on the radioactive substance storage container and the support part. For this reason, it is possible to prevent the sealed portion in the radioactive substance storage container, the container body, and the stored radioactive substance from being damaged.

  In the radioactive substance storage container support frame of the present invention, the buffer member is arranged at the bottom of the base.

  According to this radioactive substance storage container support gantry, when the buffer member falls from the base side, the buffer member plastically deforms and absorbs the impact, whereby the impact force on the radioactive substance storage container and the support portion can be reduced.

  Moreover, in the radioactive substance storage container support stand of this invention, the said buffer member is arrange | positioned inside the said base, It is characterized by the above-mentioned.

  According to this radioactive substance storage container support gantry, when the buffer member falls from the base side, the buffer member plastically deforms and absorbs the impact, whereby the impact force on the radioactive substance storage container and the support portion can be reduced.

  Moreover, in the radioactive substance storage container support stand of this invention, the said buffer member is arrange | positioned between the said radioactive substance storage container supported by the said support part, and the said base.

  According to this radioactive substance storage container support gantry, when the buffer member falls from the base side, the buffer member plastically deforms and absorbs the impact, whereby the impact force on the radioactive substance storage container and the support portion can be reduced.

  In the radioactive substance storage container support gantry of the present invention, the buffer member is arranged between the radioactive substance storage container supported by the support part and the support part.

  According to this radioactive substance storage container support frame, when the buffer member falls from the support part side, the shock-absorbing force to the radioactive substance storage container and the support part can be reduced by the buffer member being plastically deformed and absorbing the impact.

  Moreover, in the radioactive substance storage container support stand of this invention, the said buffer member is arrange | positioned between each said support part, It is characterized by the above-mentioned.

  According to this radioactive substance storage container support frame, when the buffer member falls from the support part side, the shock-absorbing force to the radioactive substance storage container and the support part can be reduced by the buffer member being plastically deformed and absorbing the impact.

  Further, in the radioactive substance storage container support frame of the present invention, the buffer member is disposed between the radioactive substance storage container supported by the support part and a floor part on which the base is placed. To do.

  According to this radioactive substance storage container support frame, when the radioactive substance storage container falls from the side open to the floor, the buffer member plastically deforms and absorbs the impact, so that the radioactive substance storage container and the support part can be absorbed. Can reduce the impact force.

  In the radioactive substance storage container support frame of the present invention, the buffer member is disposed so as to cover the radioactive substance storage container supported by the support part and the periphery of the support part.

  According to this radioactive substance storage container support frame, when the buffer member falls from the radioactive substance storage container side or the support part side, the buffer member plastically deforms and absorbs the impact, so that the impact force to the radioactive substance storage container or the support part is increased. Can be relaxed.

  In the radioactive substance storage container support frame of the present invention, the buffer member is disposed so as to cover the periphery of the radioactive substance storage container supported by the support part, the support part, and the base. .

  According to this radioactive substance storage container support frame, even if it falls from all directions, the shock-absorbing force to the radioactive substance storage container and the support part can be reduced by the buffer member being plastically deformed and absorbing the impact.

  According to the present invention, the impact force on the radioactive substance storage container and the support portion can be reduced when falling.

FIG. 1 is a longitudinal sectional view of a cask as a radioactive substance storage container supported by a radioactive substance storage container support frame according to an embodiment of the present invention. FIG. 2 is a plan sectional view of the cask shown in FIG. FIG. 3 is a side view of the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 4 is a plan view of the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 5 is a front view of the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 6 is a schematic view showing a buffer member in the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 7 is a schematic view showing a buffer member in the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 8 is a schematic view showing a buffer member in the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 9 is a schematic view showing a buffer member in the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 10 is a schematic view showing a buffer member in the radioactive substance storage container support frame according to the embodiment of the present invention. FIG. 11 is a schematic view showing the arrangement of the buffer members. FIG. 12 is a schematic diagram showing the arrangement of the buffer members. FIG. 13 is a schematic view showing the arrangement of the buffer members. FIG. 14 is a schematic view showing the arrangement of the buffer members. FIG. 15 is a schematic view showing the arrangement of the buffer members. FIG. 16 is a schematic view showing the arrangement of the buffer members. FIG. 17 is a schematic view showing the arrangement of the buffer members. FIG. 18 is a schematic view showing the arrangement of the buffer members. FIG. 19 is a schematic view showing the arrangement of the buffer members. FIG. 20 is a schematic diagram showing the arrangement of the buffer members.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

  FIG. 1 is a longitudinal sectional view of a cask as a radioactive substance storage container supported by a radioactive substance storage container support frame according to the present embodiment, and FIG. 2 is a plan sectional view of the cask shown in FIG.

  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 (not shown) can be stored. That is, the trunk body 21 is provided with a cavity 24 inside, and the cavity 24 has a columnar space with the inner peripheral surface of the cylindrical trunk body 21 as an inner wall. The basket 14 is disposed in the cavity 24. The basket 14 has a plurality of cells that individually store a plurality of radioactive substances. 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 (also referred to as an axial direction) along the cylindrical central axis of the trunk portion 12 in the cask 11 and corresponds to the vertical direction of the trunk body 21. In the present embodiment, the radioactive substance storage portion 14B is formed as shown in FIG. For this reason, in the basket body 14A, the radioactive substance storage portions 14B are partitioned and formed by combining plate-like members in a lattice shape. For this reason, a gap is formed between the inner circumferential surface of the cavity 24 and the outer circumference of the basket body 14A, and a hollow spacer capable of transferring heat is provided so as to fill the gap. 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 the forgings made from carbon steel which has a gamma ray shielding function. Stainless steel can also be used for the trunk | drum main body 21 and the bottom part 23 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 and 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 transfers 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 copper heat transfer fins 25a are provided at predetermined intervals. And the trunk | drum 12 contained the boron or the boron compound which is a polymeric material which contains many hydrogen, and has a neutron shielding function in the space part divided by the trunk | drum main body 21, the outer cylinder 25, and the heat-transfer fin 25a. A resin (neutron shield) 26 is injected and solidified through a pipe (not shown) in a fluidized state. The outer cylinder 25 is provided with lid portions that are joined to the outer peripheral surface at both ends in the vertical direction (axial direction) so as to close a gap with the outer peripheral surface of the trunk body 21.

  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. Furthermore, the trunnion 41 is being fixed to the trunk | drum 12 in the predetermined position in an outer peripheral part. The trunnion 41 is fixed to the outer periphery of the trunk body 21 and is provided so as to protrude to the outside of the outer cylinder 25. The trunnion 41 includes a large-diameter portion 41a immediately after projecting to the outside of the outer cylinder 25, and a small-diameter small-diameter portion 41b projecting further outward from the large-diameter portion 41a. The large diameter portion 41a is a portion that is supported by the support portion 3 of the support base 1 described later, and the small diameter portion 41b is a portion that engages with a hole of a suspension device (not shown) during conveyance. Although trunnion 41 is not clearly shown in the drawing, a hole into which the shaft of the suspension device is inserted may be formed at the tip of large diameter portion 41a without having small diameter portion 41b described above. Such trunnions 41 are provided at a total of four places, at least two places protruding in opposite directions on the lid 13 side and two places protruding in opposite directions on the bottom 23 side.

  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 is also formed of a stainless steel or carbon steel disk, and a resin (neutron shield) 33 is enclosed therein. The primary lid portion 31 and the secondary lid portion 32 are detachably attached to the upper end portion of the trunk body 21 with stainless steel or carbon steel bolts (not shown). In this case, metal gaskets (not shown) are interposed between the primary lid portion 31 and the secondary lid portion 32 and the trunk body 21 to ensure the internal sealing performance. The resin 33 may be provided inside the primary lid 31 or may be provided only on the primary lid 31. In addition, an auxiliary shield 34 enclosing a resin may be provided around the lid portion 13. Although not shown, a tertiary lid part may be provided on the outer side of the primary lid part 31 and the secondary lid part 32 in some cases.

  FIG. 3 is a side view of the radioactive substance storage container support frame according to the present embodiment, FIG. 4 is a plan view of the radioactive substance storage container support frame, and FIG. 5 is a front view of the radioactive substance storage container support frame. It is.

  As shown in FIGS. 3 to 5, the radioactive substance storage container support gantry (hereinafter referred to as a support gantry) 1 according to the present embodiment supports the cask 11 as the radioactive substance container described above in a lying state. is there. The support frame 1 includes a base 2 that is placed on the floor surface, and a support portion 3 that stands on the base 2 and supports the cask 11. The base 2 is formed of a steel frame and is formed in a rectangular frame shape having an opening 2a in the center in plan view. The support part 3 is formed in a columnar shape with a steel frame material, and is provided at a position corresponding to each trunnion 41 of the cask 11. The support portion 3 includes a semicircular receiving portion 3a and an upper half portion of the large-diameter portion 41a of the trunnion 41 so as to receive the lower half portion of the large-diameter portion 41a of the trunnion 41 of the cask 11 at the standing end portion. And a semicircular fixing portion 3b so as to be covered, and by fixing the fixing portion 3b to the receiving portion 3a with a bolt or the like, the large-diameter portion 41a in the trunnion 41 is inserted and supported. Yes.

  The cask 11 lifted by the suspension device via a pair of trunnions 41 (for example, two trunnions 41 on the lid 13 side) is converted into another pair of trunnions 41 (for example, two trunnions on the bottom 23 side). 41) is placed on the receiving portions 3a of the two support portions 3 facing each other on the support frame 1, and the other pair of trunnions 41 is laid down on the fulcrum so that the pair of trunnions are lifted. 41 is mounted on the receiving part 3a of the other two opposing support parts 3 so that it is supported by the support base 1 in a lying state. Moreover, the cask 11 is restrained and supported by the support frame 1 by fixing the fixing portion 3b to the receiving portion 3a. Further, the support gantry 1 on which the cask 11 is supported is lifted together with the cask 11 by lifting the cask 11 that has been laid down by a lifting device or the like via each trunnion 41 of the cask 11, for example, in the reactor building It is moved from the floor to the floor of a truck bed such as a trailer, and from the floor of the truck to the floor of the storage facility.

  6 to 10 are schematic views illustrating the buffer member, and FIGS. 11 to 20 are schematic views illustrating the arrangement of the buffer member.

  The support frame 1 described above includes a buffer member 4 as shown in FIGS. The buffer member 4 is provided so as to be able to support the load of the cask 11 and is plastically deformed by an external force to absorb an impact.

  When the support base 1 having the buffer member 4 is lifted and moved together with the cask 11 that is laid down by the suspension device or the like as described above, when there is an event of falling from the suspension device, the buffer member 4 is plasticized by an external force due to the drop. By deforming and absorbing the impact, the impact force on the cask 11 and the support portion 3 is alleviated, so that the cask 11 is prevented from detaching from the support portion 3, and the sealing portion of the lid portion 13 in the cask 11 and the container It is possible to prevent the main body 12 and the stored radioactive material from being damaged.

  Specifically, the buffer member 4 is preferably made of a ductile material. The ductile material has a property of being stretched plastically, and mainly includes a metal material. For example, when a tensile stress is applied to a metal material, it is stretched plastically and causes plastic deformation. That is, the ductile material is plastically deformed by an external force and absorbs an impact. Therefore, the impact force to the cask 11 and the support part 3 can be reduced by the buffer member 4 made of a ductile material.

  Further, as shown in FIG. 6, the buffer member 4 has a ductile material formed in a cylindrical shape (pipe shape) 4 </ b> A, and extends along the extending direction of the axis CL of the cylindrical shape 4 </ b> A in an assumed external force application direction G. Preferably they are arranged.

  In the buffer member 4 composed of such a cylindrical shape 4A, the stress of the cylindrical shape 4A when the own weight × α (external force) of the cask 11 and the support frame 1 is applied is set to be equal to or less than the stress that does not buckle. The strength of the support base 1 can be ensured. In the event of a drop, the impact force can be absorbed by the deformation of the cylindrical 4A exceeding the stress that buckles due to the impact force generated.

  In addition, as shown in FIG. 7, the buffer member 4 is preferably filled with a foam 4 </ b> Aa inside a cylindrical shape 4 </ b> A. As the foam 4Aa, for example, a synthetic resin material containing bubbles, pearlite or diatomaceous earth, or the like can be heat-treated at a high temperature. Since the above-described buckling stress is raised by filling the cylindrical body 4A with the foam 4Aa, the impact force absorption performance is increased. For this reason, the effect which relieve | moderates the impact force to the cask 11 and the support part 3 can be acquired notably at the time of fall. Further, since the impact force absorption performance is improved, the buffer member 4 can be downsized by shortening the length of the cylindrical 4A.

  Further, as shown in FIG. 8, the buffer member 4 is formed by covering a member (for example, wood or synthetic resin material) 4Ba having a predetermined compression characteristic with a covering material (for example, metal material) 4B capable of plastic deformation. It may be. Even in the buffer member 4 shown in FIG. 8, it is possible to absorb the impact by plastic deformation due to the external force caused by dropping, and to reduce the impact force to the cask 11 and the support portion 3. It is possible to prevent a situation where the sealing portion 13, the body portion 12 that is a container body, and the stored radioactive material are damaged. In addition, the desirable characteristic of the member 4Ba in the buffer member 4 is that it does not undergo large deformation up to a certain force, such as buckling, and stable (with no variation) energy absorption and deformation when exceeding a certain force. In addition, the elastic repulsion (springback) after plastic deformation is as small as possible due to plastic deformation during energy absorption.

  Further, as shown in FIG. 9, the buffer member 4 is formed by providing an orifice 4Cb at the opening of a deformable container (for example, a metal container) 4C filled with a fluid (gas or liquid) 4Ca. May be. Even the buffer member 4 shown in FIG. 9 can absorb the impact by plastic deformation due to an external force caused by dropping, and the shock absorbing characteristics of the buffer member 4 can be optimized by adjusting the shape of the orifice 4Cb. In order to alleviate the impact force on the cask 11 and the support part 3, the sealing part of the lid part 13 in the cask 11, the trunk part 12 as the container body, and the stored radioactive material are prevented from being damaged. be able to.

  As shown in FIG. 10, the buffer member 4 may be formed by filling a deformable container (for example, a metal container) 4D with a sol (or gel) 4Da. Even the buffer member 4 shown in FIG. 10 can absorb the impact by plastic deformation due to the external force due to the fall, and the cover portion of the cask 11 can be used to alleviate the impact force on the cask 11 and the support portion 3. It is possible to prevent a situation where the sealing portion 13, the body portion 12 that is a container body, and the stored radioactive material are damaged.

  The buffer member 4 shown in FIGS. 6 to 10 described above is arranged as shown in FIGS.

  In FIG. 11, the buffer member 4 is disposed at the bottom of the base 2. In addition, in FIG. 11, the buffer member 4 is arranged in multiple numbers and the baseplate 5 which supports these is provided. In addition, FIG. 11 shows a form in which a plurality of buffer members 4 are arranged, but the buffer member 4 may be a single body. According to this arrangement, when the shock-absorbing member 4 falls from the base 2 side and the shock-absorbing member 4 plastically deforms and absorbs the impact, the impact force on the cask 11 and the support portion 3 can be reduced.

  In FIG. 12, the buffer member 4 is disposed inside the base 2. In FIG. 12, a plurality of buffer members 4 are arranged, and a top plate 6 and a bottom plate 7 are provided in order to arrange them inside the base 2. 12 shows a form in which a plurality of buffer members 4 are arranged, the buffer member 4 may be a single body. According to this arrangement, when the shock-absorbing member 4 falls from the base 2 side and the shock-absorbing member 4 plastically deforms and absorbs the impact, the impact force on the cask 11 and the support portion 3 can be reduced.

  In FIG. 13, the buffer member 4 is disposed between the cask 11 supported by the support portion 3 and the base 2. That is, in FIG. 13, the buffer member 4 is disposed between the upper portion of the base 2 and the trunk portion 12 of the cask 11. According to this arrangement, when the shock-absorbing member 4 falls from the base 2 side and the shock-absorbing member 4 plastically deforms and absorbs the impact, the impact force on the cask 11 and the support portion 3 can be reduced.

  In FIG. 14, the buffer member 4 is disposed between the cask 11 supported by the support portion 3 and the support portion 3. That is, in FIG. 14, the buffer member 4 is disposed between the inside of the support portion 3 and the trunk portion 12 of the cask 11 in the upper portion of the base 2. According to this arrangement, when the shock-absorbing member 4 falls from the support part 3 side, the shock-absorbing force to the cask 11 and the support part 3 can be reduced by the plastic deformation of the buffer member 4 to absorb the impact.

  In FIG. 15, the buffer member 4 is disposed between the support portions 3. In other words, in FIG. 15, the buffer member 4 is arranged along the trunk portion 12 of the cask 11 between the support portions 3 in the upper portion of the base 2. According to this arrangement, when the shock-absorbing member 4 falls from the support part 3 side, the shock-absorbing force to the cask 11 and the support part 3 can be reduced by the plastic deformation of the buffer member 4 to absorb the impact.

  In FIG. 16, the buffer member 4 is disposed between the cask 11 supported by the support portion 3 and the floor portion F on which the base 2 is placed. The buffer member 4 shown in FIGS. 16 and 17 is disposed below the lid portion 13 and the bottom portion 23 of the cask 11. Further, the buffer member 4 shown in FIGS. 16 and 18 is disposed below the trunk 12 of the cask 11 inside the opening 2 a of the base 2. According to this arrangement, when the cask 11 falls from the side open to the floor portion F, the shock-absorbing member 4 plastically deforms and absorbs the impact, thereby reducing the impact force on the cask 11 and the support portion 3. be able to.

  In FIG. 19, the buffer member 4 is disposed so as to cover the cask 11 supported by the support portion 3 and the periphery of the support portion 3. According to this arrangement, when the shock-absorbing member 4 is plastically deformed and absorbs an impact when dropped from the cask 11 side or the support part 3 side, the impact force on the cask 11 or the support part 3 can be reduced.

  In FIG. 20, the buffer member 4 is disposed so as to cover the cask 11 supported by the support portion 3, the support portion 3, and the base 2. According to this arrangement, even if the shock-absorbing member 4 is dropped from all directions, the shock-absorbing force to the cask 11 and the support portion 3 can be reduced by the buffer member 4 being plastically deformed and absorbing the shock.

  The arrangement of the buffer member 4 shown in FIGS. 11 to 20 may be combined.

  Although not clearly shown in the drawing, in the support frame 1 of the present embodiment, the buffer member 4 may be disposed between the base 2 and the support part 3 in addition to the above-described configuration.

  According to the support frame 1, when the shock-absorbing member 4 is plastically deformed and absorbs an impact when dropped from the base 2 side, the impact force on the cask 11 and the support portion 3 can be reduced.

  Further, although not shown in the figure, in the support frame 1 of the present embodiment, the buffer member 4 may be disposed on the support portion 3 in addition to the above-described configuration.

  According to the support frame 1, when the shock-absorbing member 4 is plastically deformed and absorbs an impact when dropped from the base 2 side, the impact force on the cask 11 and the support portion 3 can be reduced.

DESCRIPTION OF SYMBOLS 1 Support stand 2 Base 3 Support part 4 Buffer member 4A Tubular 4Aa Foam 4B Cover material 4Ba Wood and synthetic resin material 4C Container 4Ca Fluid 4Cb Orifice 4D Container 4Da Sol or gel 11 Cask (radioactive substance storage container)
12 trunk 13 lid 23 bottom 41 trunnion CL axis F floor G direction of external force application

Claims (16)

In a radioactive substance storage container support frame having a base placed on the floor, and a support unit that supports the radioactive substance storage container that is placed on the base and stores the radioactive substance,
It is disposed on the base and is provided so as to be able to support the load of the radioactive substance storage container, and is plastically deformed by an external force applied to the support part to absorb an impact applied to the radioactive substance storage container and the support part. A radioactive substance storage container support frame comprising a buffer member.   The radioactive substance storage container support frame according to claim 1, wherein the buffer member is made of a ductile material.   3. The radioactive substance storage container support frame according to claim 2, wherein the cushioning member is disposed along the cylindrical axial direction in a direction in which a ductile material is formed in a cylindrical shape and an external force can be assumed. .   The radioactive substance storage container support frame according to claim 3, wherein the buffer member is filled with foam in the cylindrical shape.   2. The radioactive substance storage container support frame according to claim 1, wherein the buffer member is formed by covering a material having predetermined compression characteristics with a plastically deformable covering material.   The radioactive substance storage container support frame according to claim 1, wherein the buffer member is provided with an orifice at an opening of a deformable container filled with a fluid.   The radioactive substance storage container support frame according to claim 1, wherein the buffer member is formed by filling a deformable container with sol or gel.   The radioactive substance storage container support frame according to any one of claims 1 to 7, wherein the buffer member is disposed at a bottom portion of the base.   The radioactive substance storage container support frame according to any one of claims 1 to 7, wherein the buffer member is disposed inside the base frame. The radioactive substance storage container support frame according to any one of claims 1 to 7, further comprising a buffer member disposed between the radioactive substance storage container supported by the support portion and the base body. The radioactive substance storage container support according to claim 1, wherein the buffer member is further disposed between the radioactive substance storage container supported by the support part and the support part. Mount. Radioactive substance container support cradle according to any one of claims 1 to 7, characterized in further arranging the loose衝部material between each said support. The shock absorbing member is further disposed between the radioactive substance storage container supported by the support portion and a floor portion on which the base is placed. The radioactive substance storage container support stand. Radioactive material housed according to any one of claims 1 to 7, wherein placing said to cover the periphery of the radioactive substance container and the support portion is supported by the supporting portion loosely衝部material further Container support frame. Wherein the radioactive substance storage container supported by the support unit, according to any one of claims 1 to 7, wherein placing said support and so loose衝部material covering the periphery of the base addition The radioactive substance storage container support stand. In a radioactive substance storage container support frame having a base placed on the floor, and a support unit that supports the radioactive substance storage container that is placed on the base and stores the radioactive substance,
Between the base or the floor surface and the radioactive substance storage container supported by the support part, it is arranged in contact with the radioactive substance storage container and is provided so as to be able to support the load of the radioactive substance storage container A radioactive substance storage container support gantry comprising a buffer member that contacts the radioactive storage container and is plastically deformed by an external force and absorbs an impact applied to the radioactive substance storage container and the support portion .

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