JP5610960B2 - Nuclear fuel storage rack - Google Patents

Description

  The present invention relates to a nuclear fuel storage rack that is stored in a state where a nuclear fuel assembly is housed in water in a storage pit of a nuclear fuel storage facility.

  For example, spent nuclear fuel (used nuclear fuel rods) generated at a nuclear power plant is stored and stored in a nuclear fuel storage facility. Further, as shown in FIG. 4, the spent nuclear fuel is stored in a vertical cell (rack cell) 1 of a fuel storage rack A in a state of being accommodated in a square tube as a nuclear fuel assembly, and a storage pit 3 of a nuclear fuel storage facility 2. Stored within. At this time, water is stored in the storage pit 3, and a plurality of nuclear fuel storage racks A (nuclear fuel assemblies) are arranged and stored in the water so that the decay heat is cooled and removed below the criticality. It holds and shields radiation.

  Further, conventionally, the nuclear fuel storage rack A is fixed to the side wall 3a of the storage pit 3 via a support (anchor), and is stored in a state of being supported by the support and the storage pit 3 (see, for example, Patent Document 1). . However, when the nuclear fuel storage rack A is fixed to the storage pit 3 in this way, it is possible to obtain a seismic isolation effect to some extent by the effect of adding water to the fluid when an earthquake occurs. May increase and may not be able to support the nuclear fuel storage rack A.

  For this reason, a method for storing the nuclear fuel storage rack A without fixing it to the side wall 3a or the bottom (bottom surface) 3b of the storage pit 3 has been proposed and put into practical use (for example, see Patent Document 2). In the nuclear fuel storage facility 2 in which the nuclear fuel storage rack A is stored without being fixed to the side wall 3a or the bottom 3b of the storage pit 3, the nuclear fuel storage rack A is placed on the bottom surface 3b of the storage pit 3 so as to be slidable relative to the nuclear fuel storage rack A. The horizontal force (earthquake force) acting upon the occurrence of the earthquake is absorbed by the sliding of the nuclear fuel storage rack A together with the effect of adding water to the fluid.

  When the nuclear fuel storage rack A is configured to slide in the event of an earthquake as described above (that is, when the nuclear fuel storage rack A is configured as a free-standing rack), the nuclear fuel storage rack A is: For example, as shown in FIGS. 5, 6, and 7, the base plate 4, the four support legs 5 that are disposed on the four corners of the base plate 4 and project downward, and the base plate 4 A rack main body (cell storage unit) 6 that is provided and holds and holds a plurality of vertical cells (rack cells) 1 is formed in a substantially rectangular box shape. Further, as shown in FIG. 7, the support leg 5 includes a leg 7 that extends in the vertical direction, and a support board (base) 8 that is integrally fixed to the lower end of the leg 7. ing. Further, the rack body 6 is formed by assembling the support 6a, the cross member 6b, and the diagonal member (stay) 6c as shown in FIG. 5, or the surface surrounded by the support 6a and the cross member 6b as shown in FIG. It is formed by providing an outer peripheral plate 6d inside.

Japanese Patent Laid-Open No. 62-190494 JP 2006-162595 A

  However, when the nuclear fuel storage rack is configured to slide during an earthquake as described above, the load on the nuclear fuel storage rack and the nuclear fuel assembly is large from the four support legs to the bottom surface (bottom) of the storage pit. Pressure will act. Conventionally, since the bottom plate of the storage pit is formed by laying a stainless steel liner on the concrete slab, it is strongly desired to reduce the surface pressure so that the concrete slab of the bottom plate is not damaged. It was.

  Further, the bottom plate of the storage pit may be formed with a curved bottom surface (ground surface) on which a nuclear fuel storage rack is installed (having irregularities). For this reason, even when the bottom surface of the storage pit is curved, there has been a strong demand for a method for reliably sliding the nuclear fuel storage rack during an earthquake so that the seismic isolation effect is exhibited.

  Further, when the nuclear fuel storage rack is configured to slide, the position of the nuclear fuel storage rack is shifted due to the slide of the nuclear fuel storage rack during an earthquake. Conventionally, a transportation device that lifts, suspends and loads a nuclear fuel assembly stored in a nuclear fuel storage rack into and out of the storage pit is automatically controlled. When the position of the nuclear fuel storage rack itself is shifted due to an earthquake, It becomes necessary to take in and out nuclear fuel assemblies. For this reason, it has been strongly desired that the nuclear fuel storage rack slides and a restoring force is applied, especially during a small and medium earthquake, so that the nuclear fuel storage rack returns to its original position (returns to the original position) after the earthquake.

  In order to achieve the above object, the present invention provides the following means.

The nuclear fuel storage rack according to claim 1, wherein the nuclear fuel storage rack is installed in water in a storage pit in a state in which the nuclear fuel assembly is stored, the rack main body storing the nuclear fuel assembly, and the rack main body. A plurality of support legs provided at a lower portion of the storage pit and supporting the rack main body, and mounted on the bottom surface of the storage pit so as to slidably support the support leg and connected to the rack main body so as to be relatively movable. The pedestal is formed by making the roughness of the ground contact surface of the pedestal contacting the bottom surface of the storage pit larger than the roughness of the contact surface of the pedestal contacting the support leg. It is characterized by.

  The nuclear fuel storage rack according to claim 3 is the nuclear fuel storage rack according to claim 1 or 2, wherein the contact surfaces of the support leg and the pedestal that are in contact with each other are formed in a curved shape. Features.

  The nuclear fuel storage rack according to claim 4, wherein the pedestal is connected to the rack body or the support leg portion in the form of a cord-like connection member according to any one of claims 1 to 3. Or it is connected through an elastic body.

  The nuclear fuel storage rack according to claim 5 is the nuclear fuel storage rack according to any one of claims 1 to 4, wherein a stopper for regulating a sliding amount of the support leg relative to the pedestal is provided on the pedestal. It is provided.

  The nuclear fuel storage rack according to claim 6 is the nuclear fuel storage rack according to any one of claims 1 to 5, wherein a sphere is provided on the support leg or the pedestal, and the support is supported by the sphere. Contact surfaces of the legs and the pedestal that contact each other are formed.

  In the nuclear fuel storage rack according to claim 1, since the pedestal that is placed on the bottom surface of the storage pit and slidably supports the support legs is provided, the rack main body that stores the nuclear fuel assembly is provided in the event of an earthquake. The supporting leg portion to support can slide (slide) on the pedestal to absorb the horizontal force (earthquake force). In addition, by supporting the support legs and the rack body on the pedestal in this way, the surface pressure acting on the bottom of the storage pit can be reduced as compared with the case where the support legs are grounded to the bottom of the storage pit. It becomes possible.

  Even if the bottom surface of the storage pit is curved, the support legs slide on the pedestal, so that the nuclear fuel storage rack (rack body and support legs) can be slid reliably in the event of an earthquake. The seismic effect can be demonstrated.

  Further, since the pedestal is connected to the rack body so as to be movable relative to the rack body, that is, the pedestal is integrally connected to the nuclear fuel storage rack, the nuclear fuel storage rack is lifted and suspended to store the storage pit. The pedestal can be installed and collected in and out of the storage pit, and handling can be facilitated compared to the case where a pedestal is separately installed on the bottom surface of the storage pit.

  3. The nuclear fuel storage rack according to claim 2, wherein the roughness of the grounding surface of the pedestal contacting the bottom surface of the storage pit (surface roughness of the bottom surface of the pedestal) is the roughness of the contact surface of the pedestal contacting the support leg. Since it is set to be larger than (surface roughness of the upper surface of the pedestal), for example, during a small and medium earthquake, the support leg slides on the pedestal to absorb horizontal force, and during a large earthquake, the support leg is above the pedestal. And the pedestal can slide on the bottom surface of the storage pit to absorb the horizontal force. This makes it possible to reliably exhibit the seismic isolation effect according to the magnitude of the earthquake.

  4. The nuclear fuel storage rack according to claim 3, wherein the contact surfaces of the support leg and the pedestal that are in contact with each other are formed in a curved surface, so that the support leg and the rack are slid when the support leg slides relative to the pedestal. It is possible to apply a restoring force to the main body (nuclear fuel storage rack). This makes it possible to return the nuclear fuel storage rack to its original position (return to the origin) after, for example, a small and medium earthquake. Therefore, the nuclear fuel storage rack slides during an earthquake and a positional shift occurs, so that it is not necessary to manually put in and out the nuclear fuel assembly and adjust the position of the nuclear fuel storage rack after the earthquake.

  The nuclear fuel storage rack according to claim 4, wherein the pedestal can be moved relative to the rack body by connecting the pedestal to the rack body or the support leg portion via a cord-like connecting member such as a chain or an elastic body. Can be connected. Then, when the nuclear fuel storage rack is lifted, suspended, and put into and out of the storage pit, the pedestal is suspended and supported by the rack body or the support leg by the cord-like connecting member or elastic body, so the nuclear fuel storage rack Can be taken in and out of the storage pit and the pedestal can be easily installed and collected.

  In addition, when the pedestal is connected to the rack body or the support leg via an elastic body, when the support leg slides with respect to the pedestal, the support leg and thus the rack are moved by the elastic force (biasing force) of the elastic body. It is possible to apply a restoring force to the main body (nuclear fuel storage rack). This makes it possible to return the nuclear fuel storage rack to its original position after, for example, a small or medium earthquake. Therefore, the nuclear fuel storage rack slides during an earthquake and a positional shift occurs, and it is unnecessary to manually adjust the position of the nuclear fuel storage rack after the earthquake.

  In the nuclear fuel storage rack according to claim 5, since the stopper that regulates the sliding amount (sliding amount) of the support leg with respect to the pedestal is provided, the support leg slides greatly on the pedestal in the event of a large earthquake, for example. Thus, the base can be configured to slide on the bottom surface of the storage pit while hitting the stopper. This makes it possible to reliably exhibit the seismic isolation effect according to the magnitude of the earthquake.

  In the nuclear fuel storage rack according to claim 6, since the contact surfaces of the support leg and the pedestal that are in contact with each other are formed by a sphere, the support leg can be smoothly slid with respect to the pedestal. Makes it possible to exhibit seismic isolation effects.

It is a figure which shows the rack for nuclear fuel storage which concerns on one Embodiment of this invention. It is a figure which shows the modification of the rack for nuclear fuel storage which concerns on one Embodiment of this invention. It is a figure which shows the modification of the rack for nuclear fuel storage which concerns on one Embodiment of this invention. It is a figure which shows the storage pit of the nuclear fuel storage facility which stored the rack for nuclear fuel storage. It is a figure which shows the conventional rack for nuclear fuel storage. It is a figure which shows the conventional rack for nuclear fuel storage. It is a figure which shows the conventional rack for nuclear fuel storage.

  Hereinafter, a nuclear fuel storage rack according to an embodiment of the present invention will be described with reference to FIG. 1 (and FIGS. 4 to 7). The present embodiment relates to a nuclear fuel storage rack for storing and storing spent nuclear fuel generated at, for example, a nuclear power plant in water in a storage pit of a nuclear fuel storage facility. For this reason, the same reference numerals are given to the same components as those of the conventional nuclear fuel storage rack shown in FIGS.

  The nuclear fuel storage rack B of the present embodiment is a self-supporting rack and, like the conventional nuclear fuel storage rack A, as shown in FIG. 1 (see FIGS. 4 to 7), a rack main body for storing the nuclear fuel assembly. 6 and a plurality of support legs 5 provided at the lower part of the rack body 6 and supporting the rack body 6. The rack body 6 is formed to store and hold a plurality of rack cells 1 that contain nuclear fuel assemblies. The support leg 5 includes a leg 7 projecting downward from the rack body 6 and a substantially disk-shaped support board 8 connected to the lower end of the leg 7.

  On the other hand, in the nuclear fuel storage rack B of the present embodiment, in addition to the rack body 6 and the support legs 5, the support legs 5 are placed on the bottom surface 3b of the storage pit 3 and slidably supported. And a pedestal 10 connected to the rack body 6 so as to be relatively movable.

  And in this embodiment, the lower surface (contact surface 8a) of the support board part 8 of the support leg part 5 is formed in the convex curve shape. The pedestal 10 is formed in a substantially disk shape having a larger diameter than the support plate portion 8, and an upper surface (contact surface 10a) with which the lower surface 8a of the support plate portion 8 contacts is directed radially outward from the center O1. Accordingly, it is formed in a concave curved surface shape (in the present embodiment, a spherical shape) that gradually goes upward. Furthermore, the pedestal 10 of the present embodiment is formed with an annular stopper 11 that protrudes upward from the upper surface 10 a at the outer peripheral edge and is connected in the circumferential direction of the pedestal 10. Further, the pedestal 10 has a roughness (surface roughness) of the lower surface (ground surface) 10b that contacts the bottom surface 3b of the storage pit 3 with a roughness (surface roughness) of the upper surface (contact surface) 10a that the support leg 5 contacts. It is made larger than (a).

  The pedestal 10 formed in this way is attached to the rack body 6 by a chain (cord-like connecting member) 14 having one end attached to the mounting jigs 12 and 13 provided on the rack body 6 and the other end attached to the pedestal 10. It is connected so that relative movement is possible. At this time, at least two attachment jigs 12 and 13 are provided on the rack body 6 at equal intervals between the axis O2 of the support leg 5 and at least one of the same length with one end attached to each attachment jig 12 and 13. Two chains 14 are provided with the other ends attached to, for example, the upper end of the stopper 11 of the base 10.

  Each chain 14 is formed with such a length that a gap is created between the lower surface 8a of the support plate 8 of the support leg 5 and the upper surface 10a of the base 10 when the nuclear fuel storage rack B is suspended. Yes. Furthermore, the pedestal 10 is connected to the rack body 6 via the chain 14 so that the center O1 of the pedestal 10 is arranged on the extension line of the axis O2 of the support leg 5 in a state where the nuclear fuel storage rack B is suspended. ing. The chain 14 may be provided with one end attached to the support leg 5.

  Next, the operation and effect of the nuclear fuel storage rack B of the present embodiment having the above-described configuration will be described.

  First, the nuclear fuel storage rack B of the present embodiment is stored in the storage pit 3 of the nuclear fuel storage facility 2 by being suspended by a transfer device in a state where the nuclear fuel assembly is housed in the rack cell 1. At this time, the pedestal 10 connected to the rack body 6 via the chain 14 is first grounded to the bottom surface 3b of the storage pit 3, and the nuclear fuel storage rack B is suspended, whereby the support legs are supported on the upper surface 10a of the pedestal 10. The support plate part 8 of the part 5 comes into contact with the nuclear fuel storage rack B at a predetermined position in the storage pit 3. When the nuclear fuel storage rack B is installed in this manner, the pedestal 10 can be suspended with its center O1 placed on the extension line of the axis O2 of the support leg 5 so that the nuclear fuel storage rack B is straightened. The base 10 is installed at a predetermined position simply by hanging it down to the base 10, and the support legs 5 (and thus the rack body 6) are supported on the base 10, so that the nuclear fuel storage rack B can be easily installed. When the nuclear fuel storage rack B is taken out from the storage pit 3, the pedestal 10 can be recovered simply by lifting the nuclear fuel storage rack B.

  With the nuclear fuel storage rack B installed in the storage pit 3 in this manner, the support leg 5 and thus the rack body 6 are supported by the base 10. For this reason, compared with the case where the support leg 5 is directly grounded to the bottom surface 3b of the storage pit 3, the surface pressure acting on the bottom plate (bottom surface 3b) of the storage pit 3 is reduced.

  On the other hand, when an earthquake occurs and a horizontal force (earthquake) acts on the nuclear fuel storage rack B, the nuclear fuel storage rack B slides and absorbs the horizontal force together with the fluid addition damping effect of water in the storage pit 3. The At this time, since the roughness of the lower surface 10b is larger than the roughness of the upper surface 10a of the pedestal 10, when the acting horizontal force is small, such as during a small and medium earthquake, the space between the lower surface 10b of the pedestal 10 and the bottom surface 3b of the storage pit 3 Due to this friction, the base 10 does not slide on the bottom surface 3b of the storage pit 3, and the support leg 5 slides on the base 10 and the horizontal force is absorbed.

  Further, if the support leg 5 is configured to slide on the base 10, the support leg 5 can reliably slide on the base 10 even when the bottom surface 3 b of the storage pit 3 is curved. Horizontal force is absorbed. That is, the curvature (unevenness) of the bottom surface 3b of the storage pit 3 does not affect the seismic isolation effect, and the nuclear fuel storage rack B is surely slid to exert the seismic isolation effect.

  Further, since the contact surfaces (the lower surface 8a of the support leg 5 and the upper surface 10a of the pedestal 10) of the support leg 5 and the pedestal 10 that come into contact with each other are formed in a curved surface, when the support leg 5 slides. A restoring force acts on the support leg 5 and thus the rack body 6 (the nuclear fuel storage rack B). For this reason, after the earthquake, the nuclear fuel storage rack B automatically returns to the original position, and no position shift occurs in the nuclear fuel storage rack B (position shift is suppressed).

  Further, when a large horizontal force acts, for example, during a large earthquake, the support leg 5 slides on the base 10 to absorb the horizontal force, and between the lower surface 10b of the base 10 and the bottom surface 3b of the storage pit 3. Thus, the pedestal 10 slides on the bottom surface 3b of the storage pit 3, and the horizontal force is also absorbed by the sliding of the pedestal 10. At this time, when the pedestal 10 slides on the bottom surface 3b of the storage pit 3, no restoring force is generated, but since the roughness (surface roughness) is large, the amount of sliding can be kept small even during a large earthquake. .

  Further, at this time, since the stopper 11 is provided on the pedestal 10, when a large horizontal force acts and slides greatly, the support leg 5 hits the stopper 11 and the sliding amount is restricted. Thus, the support leg 5 hits the stopper 11, and external force acts on the stopper 11, whereby the friction between the lower surface 10 b of the pedestal 10 and the bottom surface 3 b of the storage pit 3 is broken, and the pedestal 10 becomes the bottom surface of the storage pit 3 The horizontal force is absorbed by sliding on 3b. In addition, the effect which absorbs a horizontal force with the impact force with which the support leg part 5 hits the stopper 11 is also acquired.

  Therefore, in the nuclear fuel storage rack B of the present embodiment, the pedestal 10 that is placed on the bottom surface 3b of the storage pit 3 and slidably supports the support legs 5 is provided. The support leg 5 that supports the rack main body 6 that stores the slidable (sliding) on the base 10 can absorb the horizontal force (earthquake force). The support legs 5 and thus the rack body 6 are supported by the pedestal in this way, so that the support legs 5 act on the bottom 3b of the storage pit 3 as compared with the case where the support legs 5 are grounded to the bottom surface 3b of the storage pit 3. It becomes possible to reduce the surface pressure.

  Further, even if the bottom surface 3b of the storage pit 3 is curved, the support leg 5 slides on the base 10, so that the nuclear fuel storage rack B (the rack body 6 and the support leg 5) during an earthquake. Can be reliably slid to exhibit the seismic isolation effect.

  Further, since the pedestal 10 is connected to the rack body 6 so as to be relatively movable (because the pedestal 10 is integrally connected to the nuclear fuel storage rack B), the nuclear fuel storage rack B is lifted and suspended. Thus, the pedestal 10 can be installed and collected in and out of the storage pit 3, and handling can be facilitated as compared with the case where a pedestal is separately installed on the bottom surface 3 b of the storage pit 3. That is, when the pedestal is separately installed, only the pedestal is installed in advance while adjusting the position of the pedestal 3 on the bottom surface 3b of the storage pit 3. Therefore, a great deal of labor is required, but the pedestal 10 is a nuclear fuel storage rack. By being integrally connected to B, the base 10 can be easily installed and collected.

  Further, as in the present embodiment, the pedestal 10 can be relatively moved with respect to the rack body 6 by connecting the pedestal 10 to the rack body 6 (or the support leg portion 5) via a chain (cord-like connecting member) 14. Can be connected to. When the nuclear fuel storage rack B is lifted, suspended, and put into and out of the storage pit 3, the pedestal 10 can suspend and support the rack body 6 (or the support leg 5) by the chain 14, and the nuclear fuel storage The rack B can be taken in and out of the storage pit 3 and the pedestal 10 can be easily installed and collected.

  Furthermore, in the nuclear fuel storage rack B of the present embodiment, the roughness of the grounding surface (lower surface) 10b of the pedestal 10 that contacts the bottom surface 3b of the storage pit 3 is the contact surface of the pedestal 10 that the support leg 5 contacts ( Since the roughness of the upper surface 10a is set to be larger than that of the upper surface 10a, for example, the support leg 5 slides on the pedestal 10 to absorb horizontal force during a small and medium-sized earthquake, and the support leg 5 is pedestal 10 at a large earthquake. The pedestal 10 can slide on the bottom surface 3b of the storage pit 3 and can absorb the horizontal force. This makes it possible to reliably exhibit the seismic isolation effect according to the magnitude of the earthquake.

  Further, the contact surfaces 8a and 10a of the support leg 5 and the pedestal 10 that come into contact with each other are formed in a curved shape, so that when the support leg 5 slides with respect to the pedestal 10, the support leg 5 and thus the rack. A restoring force can be applied to the main body 6 (nuclear fuel storage rack B). Thereby, for example, after a small and medium earthquake, the nuclear fuel storage rack B can be returned to the original position (return to the origin). As a result, the nuclear fuel storage rack B slides during an earthquake and a positional shift occurs, and it is unnecessary to manually adjust the position of the nuclear fuel storage rack B after the earthquake.

  Further, by providing the stopper 11 that regulates the sliding amount (sliding amount) of the support leg 5 with respect to the pedestal 10, the support leg 5 slides greatly on the pedestal 10 and hits the stopper 11 at the time of a large earthquake, for example. At the same time, the base 10 can be configured to slide on the bottom surface 3 b of the storage pit 3. This makes it possible to reliably exhibit the seismic isolation effect according to the magnitude of the earthquake.

  As mentioned above, although one embodiment of the nuclear fuel storage rack according to the present invention has been described, the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

  For example, as shown in FIG. 2, the support leg 8 may include a sphere 15, and the contact surface 8 a (15 a) of the support leg 5 may be formed by the sphere 15. In this case, the support leg 5 can be slid more smoothly with respect to the pedestal 10 than in the case where the contact surface 8a of the support leg 5 is formed in a curved shape as in this embodiment. The seismic effect can be demonstrated. In FIG. 2, a sphere is provided on the support leg 15, but a plurality of spheres 15 are provided on the pedestal 10, and the contact surface 10 a (15 a) of the pedestal 10 is formed by these spheres 15. In this case, the same effect as described above can be obtained.

  In this embodiment, the pedestal 10 is connected to the rack body 6 so as to be movable relative to the rack body 6 by using a chain (cord-like connecting member) 14. For example, as shown in FIG. 6 or the support leg 5 may be connected via an elastic body 16 such as a spring. In this case, as in the present embodiment, when the nuclear fuel storage rack B is lifted, suspended, and put into and out of the storage pit 3, the base 10 is supported by the elastic body 16 so that the pedestal 10 is supported by the rack body 6 or the support leg 5. Therefore, the nuclear fuel storage rack B can be taken in and out of the storage pit 3 and the pedestal 10 can be easily installed and recovered.

  Further, when the support leg 5 slides with respect to the pedestal 10, a restoring force is applied to the support leg 5 and thus the rack body 6 (nuclear fuel storage rack B) by the elastic force (biasing force) of the elastic body 16. Is possible. Thereby, it becomes possible to return the nuclear fuel storage rack B to its original position after, for example, a small and medium earthquake. Therefore, even in this case, the nuclear fuel storage rack B slides during the earthquake, causing a positional shift, and it is unnecessary to manually adjust the position of the nuclear fuel storage rack B after the earthquake.

1 Rack cell 2 Nuclear fuel storage facility 3 Storage pit 3a Side wall 3b Bottom (bottom plate, bottom)
4 Base plate 5 Support leg 6 Rack body (cell storage)
6a Post 6b Cross member 6c Diagonal member 6d Outer plate 7 Leg 8 Supporting plate (pedestal)
8a Bottom surface (contact surface)
10 Base 10a Upper surface (contact surface)
10b Bottom surface (grounding surface)
11 Stopper 12 Mounting jig 13 Mounting jig 14 Chain (Rope-shaped connecting member)
15 Sphere 15a Contact surface 16 Elastic body A Conventional nuclear fuel storage rack B Nuclear fuel storage rack O1 Center axis O2 axis of support leg

Claims (5)

A nuclear fuel storage rack installed in the water in the storage pit with the nuclear fuel assembly stored therein,
A rack body for storing the nuclear fuel assembly;
A plurality of support legs provided at a lower portion of the rack body to support the rack body;
A pedestal mounted on the bottom surface of the storage pit and slidably supporting the support leg, and connected to the rack body so as to be relatively movable ;
The pedestal is formed by making the roughness of the ground contact surface of the pedestal contacting the bottom surface of the storage pit larger than the roughness of the contact surface of the pedestal contacting the support leg. Nuclear fuel storage rack. The nuclear fuel storage rack according to claim 1 ,
A nuclear fuel storage rack, wherein contact surfaces of the support leg and the pedestal contacting each other are formed in a curved surface. The nuclear fuel storage rack according to claim 1 or 2 ,
A nuclear fuel storage rack, wherein the pedestal is connected to the rack main body or the support leg portion via a cable-like connecting member or an elastic body. The nuclear fuel storage rack according to any one of claims 1 to 3 ,
A nuclear fuel storage rack, wherein the pedestal is provided with a stopper for restricting a sliding amount of the support leg with respect to the pedestal. The nuclear fuel storage rack according to any one of claims 1 to 4 ,
A nuclear fuel storage rack, wherein a sphere is provided on the support leg or the pedestal, and a contact surface between the support leg and the pedestal is formed by the sphere.

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