JPH11258391A - Transport cask of reactor fuel and its transport method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact and large capacity transport cask of reactor fuel and its transport method which resolves biasing problem of fuel or fuel protection vessel in a basket hole of a fuel transport cask. SOLUTION: A fuel transport cask 10 is to directly or indirectly contain fuel assemblies 11 of reactor fuel in a fuel protection vessel in basket holes 20 in a basket 12 and to transport. The fuel transport cask 10 is provided with a fuel biasing device 40 supporting the fuel assemblies 11 inserted in the basket holes 20 or fuel protection vessel, moving and biasing in the direction crossing to the insertion direction and a fuel fixing device 23 fixing fuel assemblies 11 inserted in the basket holes 20 fuel protection vessel. The fuel biasing device 40 is placed at the bottom of the basket 12 or a basket hole inner bottom.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactor container and a method for transporting and storing a reactor fuel, and more particularly to a compact reactor capable of simultaneously transporting a large number of light water reactor fuels such as mixed oxide fuel bodies. The present invention relates to a large-capacity nuclear fuel transport container and a transport method thereof.

[0002]

2. Description of the Related Art In a light water reactor such as a boiling water reactor or a pressurized water reactor, a mixed oxide fuel (hereinafter, referred to as a MOX fuel) is used as a reactor fuel. This MOX
After the fuel body is made in the fuel processing facility, it is stored and protected in a fuel protection container, and the fuel protection container is loaded on a fuel transport container for transportation.

[0003] When a light water reactor fuel is transported like a MOX fuel body, if vibrations are applied to the light water reactor fuel, abrasion occurs at a metal contact portion, which is not preferable in terms of maintaining economy and reliability of the light water reactor fuel. In the case of spent fuel, no special measures are taken to prevent vibration, since slight wear caused during transportation is not a problem. Since spent fuel does not require any special measures against vibration, a fuel transport container for spent fuel is structurally simple, and a compact and large-capacity fuel container capable of storing a large number of spent fuels has been developed.

On the other hand, in transporting a new fuel body of MOX fuel, since the MOX fuel body is used as a reactor fuel after the transportation, it is necessary to take measures to prevent vibration during transportation from the viewpoint of soundness and reliability. Specifically, it is necessary to store the new fuel body directly or after storing the fuel protection container containing the new fuel body in a basket of the fuel transport container, and then restrain and secure the new fuel body to the basket by some method. that time,
The ratio of the space occupied by the lashing device in the basket has increased, which has been a factor inhibiting the development of a large-capacity and compact fuel transport container capable of storing a large number of new fuel bodies at the same time. Therefore, a compact and large-capacity fuel transport container for new MOX fuel comparable to a fuel transport container for spent fuel has not been developed.

In transporting a new MOX fuel body, it is very difficult to store the new MOX fuel body in a relatively rigid protective container or inner container in which a protective material or a cushioning material is provided, and transport the new MOX fuel body in the fuel transport container. General. In the conventional fuel transport container, when the MOX new fuel body is directly inserted into the narrow basket hole, the opening area of the basket hole may be increased to some extent because contact scratches may occur at the time of insertion.
Further, in the basket hole, it is difficult to perform so-called "skew", so that it was necessary to press and secure the four side surfaces of the new fuel body without shifting. For this reason, the space occupied by the fuel lashing device in the fuel transport container becomes large, and the occupied space of the fuel lashing device may be larger in the whole fuel transport container than when the fuel protection container is used. .

[0006] Here, the term "skew" means to move a fuel body vertically inserted into a basket hole of a fuel transport container so as to contact two inner side surfaces adjacent to the basket hole. However, since the fuel body has a low bending rigidity, when the fuel body is pressed and moved from one side or two sides in the basket hole, the fuel body itself may be bent, which is one of the causes of the difficulty in biasing. Has become.

If the fuel body can be directly stored in the basket hole of the fuel transport container and transported without being stored in the fuel protection container, the fuel transport container can be made compact and the transport cost can be reduced. However, the fuel body has low bending rigidity,
Due to the problem of misalignment, the fuel has not been transported by directly storing it in the basket hole of the fuel transport container.

On the other hand, when the MOX new fuel body is accommodated in the fuel protection container and transported by the fuel transport container, the following problem of misalignment arises.

When the MOX new fuel assemblies are housed together in the fuel protection container one by one, there is no major problem with offsetting because the weight of the protection container containing the fuel assemblies is relatively light.
On the other hand, recently, for the purpose of downsizing and increasing the capacity of the fuel transport container, the use of a fuel protective container capable of accommodating a plurality of fuel members such as four is under study. In this case, there has been a problem that the weight of the fuel protection container containing the fuel body is increased, so that it is difficult to offset the fuel.

[0010]

In this type of nuclear fuel transport container, development of a more compact and large-capacity fuel transport container is strongly expected. In developing this fuel transport container, a case where a light water reactor fuel body such as a new MOX fuel body is directly stored and transported in the basket hole, or a case where the fuel body is stored in the fuel protection container and the protection container is stored in the basket hole There is a problem that the fuel body or the fuel protection container must be offset in the basket hole when transporting the fuel.

The present invention has been made in view of the above circumstances, and solves the problem of misalignment of a fuel body or a fuel protection container in a basket hole of a fuel transport container, and provides a compact and large-capacity atom. An object of the present invention is to provide a container for transporting furnace fuel and a method for transporting the same.

Another object of the present invention is to stably store a fuel body or a fuel protection container for a reactor fuel such as a MOX fuel body in a basket hole, to improve the soundness and reliability of fuel transportation, and to reduce the size of the fuel. And a method for transporting a large-capacity nuclear reactor fuel.

Still another object of the present invention is to effectively and sufficiently exert a securing effect with a small tightening force, solve the problem, and transport nuclear reactor fuel capable of transporting a large number of reactor fuel simultaneously. A container and a method for transporting the container are provided.

Another object of the present invention is to provide a reactor container and a method of transporting a reactor fuel capable of simultaneously and soundly transporting a large number of fuel bodies of the reactor fuel and reducing transport costs. .

[0015]

According to a first aspect of the present invention, there is provided a transport container for a nuclear fuel, comprising: In a fuel transport container to be stored and transported directly or indirectly in a fuel protection container, the fuel body or the fuel protection container inserted into the basket hole is supported and moved in a direction orthogonal to the insertion direction. And a fuel securing device for securing a fuel body or a fuel protection container inserted into the basket hole, wherein the fuel biasing device comprises a bottom portion of the basket or a bottom portion in the basket hole. It is provided in.

According to another aspect of the present invention, there is provided a nuclear reactor fuel transport container, wherein the fuel biasing device includes a fuel assembly inserted into a basket hole. Alternatively, it is provided with a fuel support device for supporting the tip of the fuel protection container, and a drive device for moving the support device in a direction perpendicular to the direction in which the fuel body is inserted.

Further, in order to solve the above-mentioned problems,
In the fuel container for transporting nuclear fuel according to the present invention, as described in claim 3, the fuel support device includes a fuel receiving stand that supports a fuel body inserted into a basket hole or a tip portion of a fuel protection container, and And a flotation device utilizing pressurized gas for levitating the pedestal. Also, as described in claim 4, the fuel support device is provided with a fuel body or a fuel protection container inserted into a basket hole. A fuel cradle that supports the tip and a roller that supports this cradle in a shiftable manner,
And a slide support device such as a bearing.

Further, in order to solve the above-mentioned problems, a fuel container for a nuclear reactor according to the present invention comprises: a basket body having a plurality of basket holes; A support receiving space is formed between the supporting member and a basket bottom plate fixed to the bottom of the fuel supporting device. The fuel support device and the driving device constitute a fuel biasing device, and the fuel biasing device is configured to simultaneously move all the fuel bodies or all the fuel protection containers inserted into the basket holes and bias them. The fuel support device may further include a levitation device using a pressurized gas or a slide support device in the support storage space. The fuel biasing device is provided, and the fuel biasing device simultaneously moves all the fuel bodies or all the fuel protection containers inserted into the basket holes by the driving device while supporting the fuel supporting device so that the fuel supporting device can float or shift at the same time. It is configured to be biased.

Still further, in order to solve the above-mentioned problems, a container for transporting nuclear fuel according to the present invention, as described in claim 7, has a fuel body or a fuel protection container at the bottom inside each basket hole of the basket. A fuel receiver is provided for each of the basket holes, and a driving device is provided for moving the fuel receiver in a direction perpendicular to the insertion direction of the fuel body. A biasing device is provided for each basket hole, and the fuel biasing device is configured to move the fuel body or the fuel protection container inserted into the basket hole for each basket hole to bias the fuel. 9. The fuel receiving device according to claim 8, wherein the fuel supporting device is provided at a bottom of each basket hole via a floating device or a slide supporting device using pressurized gas. The fuel biasing device includes a fuel body or a fuel protection container inserted into a basket hole, which is moved by a driving device while being supported by a fuel supporting device so as to be able to float or shift, and is biased. is there.

Further, in order to solve the above-mentioned problems,
In the transport container for nuclear fuel according to the present invention, each of the basket holes of the basket and the fuel body or the fuel protective container are configured in a rectangular tube shape, and the fuel transport container is set in a horizontal state. The two inner wall surfaces adjacent to the basket hole in contact with the offset fuel body or fuel protection container are located below the fuel body or fuel protection container, and the inner wall of the basket hole is inclined at an acute angle from horizontal. The fuel body or the fuel protection container is supported by the inside wall surface of the basket hole having a V-shaped cross section.

In order to solve the above-mentioned problems, the method for transporting nuclear fuel according to the present invention is characterized in that the fuel transport container is set upright and the fuel transport container is set vertically. In the method of loading a fuel body, and a method of transporting nuclear fuel having a step of transferring the fuel transport container from each fuel facility to a nuclear power plant or another fuel facility with the fuel transport container placed in a horizontal state, the fuel loading step includes: After inserting the fuel body of the reactor fuel directly into the basket hole of the fuel transport container or indirectly by inserting it into the fuel protection container, the tip of the fuel body or the fuel protection container is moved by the fuel biasing device and biased. A fuel body or a fuel protection container displaced by the fuel securing device is secured in the basket hole to load the fuel body or the fuel protection container in the basket hole. A.

Further, in order to solve the above-mentioned problem,
In the method for transporting nuclear reactor fuel according to the present invention, as described in claim 11, in the fuel loading step, the tip of all the fuel bodies or the entire fuel protection container inserted into each basket hole of the fuel transport container is removed. Supported by the fuel support of the fuel support device,
This fuel pedestal is driven by a driving device to shift all the fuel bodies or all the fuel protection containers simultaneously, and after this one-sided movement, the fuel locking device is used to secure the fuel bodies or the fuel protection containers. As described in claim 12, in the fuel loading step, all the fuel bodies or the front ends of all the fuel protection containers inserted into the respective basket holes of the fuel transport container are supported by the fuel cradle of the fuel support device. And
While the fuel cradle is levitated or slidably supported by a levitation device or a slide support device using a pressurized gas, the fuel cradle is driven by a driving device to levitate or slide all the fuel bodies or all the fuel protection containers simultaneously. This is a method of causing the sheets to be offset at the same time.

Furthermore, in order to solve the above-mentioned problems, a method for transporting nuclear fuel according to the present invention is described in claim 13.
As described in the above, in the fuel loading step, the front end of the fuel body or the fuel protection container inserted by the fuel receiving pedestal installed at the bottom of each basket hole of the fuel transport container is supported and inserted into the basket hole. The fuel assembly or the fuel protection container is moved individually by the fuel biasing device provided for each basket hole, and subsequently or simultaneously with the biasing, the fuel securing device or the fuel protection container is moved by the fuel securing device. 15. The method according to claim 14, wherein the protection container is secured in the basket hole, and in the fuel loading step, the fuel receiving pedestal of the fuel support device is installed in each basket hole of the fuel transport container. The fuel support or the tip of the fuel protection container is supported by the above, and the above-mentioned fuel receiving table is levitated or slid by a flotation device or a slide support device using pressurized gas. By driving the fuel receiving pedestal by the driving device while supporting as much as possible, the fuel body or the fuel protection container is lifted or slid, and the fuel body or the fuel protection container inserted into each basket hole is individually biased. is there.

Still further, in order to solve the above-mentioned problems, a method for transporting nuclear fuel according to the present invention is provided in claim 15.
As described in the above, in the fuel transfer step, two inner wall surfaces adjacent to the basket hole which is in contact with the fuel body or the fuel protection container which is offset in the basket hole are positioned below the fuel body or the fuel protection container. In this method, the inner wall of the basket hole is installed so as to be inclined at an acute angle from the horizontal, and the fuel body or the fuel protection container is transferred while being supported by two adjacent inner surfaces of the basket hole having a V-shaped cross section. .

[0025]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a longitudinal sectional view showing a first embodiment of a nuclear reactor fuel transport container according to the present invention. In the figure, reference numeral 1
Numeral 0 denotes a fuel transport container for directly storing the rectangular tubular MOX fuel body 11 as light water reactor fuel. This fuel transport container 10
Is suitable for storing not only a MOX fuel body but also a new fuel body of a reactor fuel such as a UO ₂ fuel body. Fuel transport container 10
Is provided with a basket 12 for directly storing the fuel body 11, eliminating the need for a fuel protection container for housing the fuel body 11. The basket 12 has a columnar or cylindrical shape as a whole, and the basket 12 is set in a transport container body (not shown) to constitute the fuel transport container 10.

The basket 12 of the fuel transport container 10 includes a cylindrical or cylindrical basket body 13, a basket bottom plate 14 as a bottom cover fixed to the bottom of the basket body 13, the basket bottom plate 14 and the basket body 13. , And a fuel receiving plate 15 as a fuel receiving base. A support storage space 16 is recessed above the basket bottom plate 15, and the fuel body receiving plate 15 is stored in the storage space 16 so as to float. The support storage space 16 may be formed by recessing the bottom of the basket body 13.

The fuel body receiving plate 15 is provided in the support storage space 1.
6, and constitutes a fuel support device 17 that supports the lower end of the fuel body 11 so that it can float or shift.

On the other hand, the basket main body 13 includes a large number of cylindrical basket hole elements 18 made of a square tube or a square tube as basket constituent members.
Are connected to each other by a connecting member 19 and integrated into an aligned arrangement. In the basket hole element 18, a square cylindrical basket hole 20 constituting a fuel storage chamber is formed. The fuel body 11 is housed in the basket hole 20, and the housed fuel body 11 is positioned and supported by fitting a tip end thereof to a fuel receiving portion 21 recessed on the fuel receiving plate 15. You.

Each basket hole 20 of the basket body 13
The fuel body 11 inserted into the fuel cell 11 is fastened and secured by the fuel securing device 23 shown in FIG. A plurality of fuel securing devices 23 are attached to two adjacent outer walls of the basket hole element 18 at appropriate intervals in the axial direction, and support the clamping plate 24 in the basket hole 20 so as to be able to advance and retreat.

The fastening directions of the fuel securing device 23 installed in each basket hole element 18 are two directions common to all the basket holes 20. In the drawing shown in FIG. It is obliquely upward. By driving the fuel securing device 23, the fastening plate 24 is moved forward and backward between the storage position in the basket hole 20 and the projecting position in a direction orthogonal to the insertion direction of the fuel body 11. By driving the fuel securing device 23, the fastening plate 2
When the fuel rod 4 is projected into the basket hole 20, the fuel body 11 inserted into the basket hole 20 is pressed by the fastening plate 24, and is clamped and secured on the V-shaped side wall surface in the basket hole 20. Has become. In FIG. 2, reference symbol d indicates a distance by which the fuel body 11 inserted into the basket hole 20 is shifted.

When the fuel assembly 11 is actually transported, the fuel transport container 10 is turned from the vertical position to the horizontal position,
In FIG. 2, the left side is set downward. FIG. 5 shows an arrangement relationship of the basket 12 when the fuel body 11 is transported. During this fuel transport, the basket 12 is set such that the inner wall (axis) of the basket hole 20 is at an acute angle to the horizontal, for example, at an angle of about 45 degrees.

FIG. 2 shows an example in which the fuel securing device 23 is installed on two adjacent V-shaped side walls of the basket hole element 18 from the outside. It may be installed in. Fuel securing device 2
3 is installed on the diagonal line of the basket hole element 18, the cross section of the fastening plate 24 is formed in a V shape, and the fastening plate 24 may be moved forward and backward from each diagonal direction in each basket hole 20. Does not require two directions.

A plurality of connecting columns 25 are integrally provided on the bottom surface of the basket body 13 at appropriate intervals in the circumferential direction and project downward, and each connecting column 25 is connected to the basket bottom plate shown in FIG. 14 and are firmly connected. The connection holes 26 of the basket bottom plate 14 are formed at positions corresponding to the connection columns 25, respectively.
7. The connecting device 27 is provided for the basket bottom plate 1.
4 and a connecting hole is provided on the basket body 13 side, or the basket body 13 is tightened with bolts or the like.
And the basket bottom plate 14 may be fastened, and various connecting means are conceivable.

On the other hand, in consideration of the one-sided movement of the fuel receiving plate 15, the support receiving space 16 recessed on the basket bottom plate 14 has a moving direction dimension d that is smaller than the fuel receiving plate 15 as shown in FIG. Only _one big. The moving direction dimension d ₁ is set to be equal to the offset moving distance d of the fuel body 11. The support storage space 16 has substantially the same shape as the fuel receiving plate 15. That is, the fuel receiving plate 15 is installed in the support accommodating space 16 so as to be movable by a moving distance due to the offset of the fuel body 11.

When the fuel receiving plate 15 is shifted toward the right end of the support storage space 16 as shown in FIG. 3, the position of the fuel receiving portion 21 is located at the center of each basket hole 20. Therefore, when the fuel body 11 is inserted into the center of the basket hole 20, the fuel body 11 is fitted and placed on the fuel receiving portion 21. The fuel receiving portion 21 is formed in a tapered shape, a dish shape, or a trumpet shape so as to expand upward.

A ring-shaped, torus-shaped or skirt-shaped support leg 29 protrudes from the lower surface of the fuel receiving plate 15 constituting the support device 17 for the fuel body 11. A pressurized gas supply space 30 is formed on the bottom surface of the body storage space 16. A gas supply hole 31 is opened as shown in FIG. 1 so as to face the pressurized gas supply space 30. The gas supply hole 31 is connected to a gas supply source (not shown) via a gas supply pipe 32, Board 1
The flotation device 33 for levitating the fifth device 5 is configured. The flotation device 33 can supply a pressurized gas such as high-pressure air to the pressurized gas supply space 30 from the upper side of the basket 12. This flotation device 33 cooperates with the fuel receiving plate 15,
The fuel support device 17 is constituted.

A driving device 35 for moving the fuel receiving plate 15 is provided beside the fuel receiving plate 15. In this drive device 35, a drive mechanism 36 such as a four-bar drive link mechanism is connected to the fuel receiving plate 15.
Is driven by the rotating shaft 37. Rotary axis 3
7 is set on the side of the basket 12, and the basket 12
The rotary shaft 37 is driven to rotate linearly or by a motor from above. The drive mechanism 36 is driven by the rotation of the rotation shaft 37, and the fuel receiving plate 15 is configured to be able to move forward and backward within the support storage space 16.

The driving device 35 and the fuel support device 17 having the levitation device 33 constitute a fuel biasing device 40. Each basket hole 2 is
The tip of the fuel body 11 inserted in the cylinder 0 can be simultaneously shifted. Next, a method of transporting the reactor fuel will be described.

The method of transporting the reactor fuel is as follows.
0, the fuel body 11 of the reactor fuel is inserted into each of the basket holes 20 of the basket 12 and loaded, and the fuel transport container 10 is placed in the horizontal state from each fuel facility to the nuclear power plant or It is roughly divided into the step of transferring to another fuel facility.

In the fuel loading step of the reactor fuel, the fuel receiving plate 15 accommodated in the basket 12 is moved to the position shown in FIGS.
, And the fuel receiving plate 15 is positioned so as to be closer to the right end of the support storage space 16. With the fuel receiving plate 15 moved toward the right end, the fuel body 11 is inserted into the center of each basket hole 20, and its tip is fitted to the receiving portion 21 of the fuel receiving plate 15 and placed.

After all the fuel bodies 11 are inserted into the respective basket holes 20 of the basket 12, a pressurized gas such as high-pressure air is supplied to the pressurized gas supply space 30 below the fuel receiving plate 15.
While the pressurized gas is continuously supplied, the fuel receiving plate 15 on which the fuel body 11 is placed is slightly levitated by the levitating device 33. In this floating state, the driving device 35 is driven, the fuel receiving plate 15 is moved laterally by the drive mechanism 36, and all the bottoms (tips) of the fuel bodies 11 accommodated in the respective basket holes 20 are simultaneously moved. Let it approach.

At this time, the drive mechanism 36 includes, for example, a screw shaft with left and right threads cut on a rotating shaft 37,
A pair of boss-shaped slide blocks 38 are screwed to the screw shaft. Each slide block 38 is connected to the fuel receiving plate 15 via the connecting link 39 of FIG. 1 to form a four-bar drive link mechanism 36.
The rotation of the rotation shaft 37 causes the pair of slide blocks 38 to move in a direction approaching or moving away from each other, and the movement of the slide blocks 38 causes the fuel receiving plate 15 to move between the fuel body receiving position and the offset position. You can move back and forth. Instead of the drive link mechanism, various drive mechanisms such as a pinion rack mechanism and a worm gear mechanism may be employed as the drive mechanism 36.

Next, the fuel securing device 23 installed in each basket hole element 18 is driven for each individual fuel body 11 so that the fastening plate 24 projects from the storage position, and the fuel body 11 is pressed and fastened. . The bottom of the fuel body 11 is the fuel body biasing device 4
0, the fuel assembly 11 has been already shifted by the tightening plate 24, so that the entire fuel assembly 11 can be shifted stably, smoothly and easily.

As described above, the fuel bodies 11 accommodated in the respective basket holes 20 are sequentially tightened and secured by the fuel securing apparatus 23, so that all the fuel bodies 11 are secured by the fuel securing apparatus 23. Can be done. When the fuel body 11 is sequentially secured by the fuel securing device 23 and the loading of the fuel body 11 into the fuel transport container 10 is completed, the fuel transport container 10 is transferred from each fuel facility to the nuclear power plant or another fuel facility. For fuel transportation.

FIG. 4 shows a state in which the fuel transport container 10 directly housing the fuel body 11 is placed in a horizontal state, which is a state at the time of fuel transfer, and is a diagram in which the top of the basket 12 is viewed obliquely from above.

As shown in FIG. 4, the fuel assembly 11 is biased by the fuel biasing device 40 in each basket hole 20 of the fuel transport container 10, and the tightening plate 24 of the fuel securing device 23.
And tied up. At this time, two adjacent V-shaped inner wall surfaces of the basket hole 20 in contact with the fuel body 11 are located below the fuel body 11 and the basket hole 2
The 0 inner wall is kept at an acute angle from the horizontal direction, for example, inclined at about 45 degrees. The fuel body 11 secured by the fuel securing device 23 is in contact with the inner wall surface of the V-shaped basket hole 20 inclined at an acute angle, for example, about 45 degrees from horizontal, and its own weight is supported. As shown in FIG. 5, the weight of the fuel receiving plate 15 is also supported by two V-shaped inner wall surfaces of a support storage space 16 provided in the basket bottom plate 14.

In the method of transporting nuclear fuel, in the fuel transfer step, the basket hole 2 with which the offset fuel body 11 is in contact.
0 are located on the lower side of the fuel body 11, and each bust hole 20 has an axis inclined by about 45 degrees from the horizontal, and the fuel body 11 has two basket holes 20 having a V-shaped cross section. It is stably transported while being supported by the inner wall surface.

In this method of transporting nuclear fuel, both the fuel body 11 and the fuel receiving plate 15 which is a part of the fuel biasing device 40 when the fuel transport container 10 is placed in a horizontal state during the fuel transfer. Are supported by the two V-shaped inner wall surfaces of the basket hole 20, and are extremely stable against vibration during the transfer of the reactor fuel. For this reason, the fastening force of the fuel securing device 23 can be reduced from above, and the fuel securing device 23 can be reduced in size, and the compact and large-capacity fuel transport container 10 and the transport method thereof can be provided.

Further, in the fuel transport container shown in FIGS. 1 to 5, an example is shown in which the fuel body 11 of the reactor fuel is directly accommodated in the basket hole 20 of the fuel transport container 10. When the fuel body 11 is directly accommodated in the basket hole 20, a fuel protection container is not required, and the fuel transport container 10 is not required.
Therefore, even if the fuel transport container 10 is made compact, a large number of fuel bodies 11 can be stored and transported at the same time.

In this embodiment, the fuel body 11 is not housed in the fuel protection container, but is directly in the basket hole 2 of the fuel transport container 10.
This problem has been solved by providing the fuel biasing device 40, which is a problem of biasing the fuel body 11 which is the biggest problem in storing and transporting the fuel in the fuel container 10. The fuel transport container 10 is compact and has a large capacity. And the cost of fuel transportation can be reduced.

In the container for transporting nuclear fuel shown in FIGS. 1 to 5, the MOX fresh fuel body is directly stored in the basket hole 20 of the fuel transport container 10 and transported without being stored in the fuel protection container. The technique of shifting the fuel body 11 has been described.
The problem of misalignment also arises when a fuel protection container containing four fuel bodies is used. Fuel transport container 10 of the present embodiment
Needless to say, the transportation method can be applied to the case where a fuel protection container is used.

Further, in the fuel transport container shown in FIG. 1, a flotation device 33 for lifting the fuel receiving plate 15 is provided at the bottom of the basket 12 of the fuel transport container 10.
Although the example in which the flotation device 33 is provided in the fuel support device 17 is shown, instead of having the flotation device 33 in the fuel support device 17, the fuel receiving plate 15 is supported by the slide support device 44 as shown in FIG. Is also good. By providing the slide support device 44 in the fuel support device 17, the fuel receiving plate 15 is stably and smoothly slidably supported in the support storage space 16. The slide support device 44 is configured by interposing rollers, bearings, and the like between the fuel receiving plate 15 and the support storage space 16.

FIG. 6 shows that the fuel support device 17 has a slide support device 44 and the fuel receiving plate 15 is connected to the slide support device 4.
The support storage space 16 is slidably supported through the support member 4.

By supporting the fuel receiving plate 15 accommodated in the support accommodating space 16 via the slide supporting device 44, the fuel receiving plate 15 is driven by the driving device 35.
The support body storage space 16 can be smoothly and smoothly slid over the bottom surface of the support body storage space between the fuel body insertion / removal position and the one-sided position. The entire fuel assembly 1 supported on the fuel receiving portion 21 by sliding the fuel receiving plate 15
One or the lower part of the fuel protection container can be simultaneously and stably and smoothly slid and shifted.

FIGS. 7 and 8 show a second embodiment of a reactor fuel transport container according to the present invention.

FIGS. 7 and 8 show one basket hole element 18 constituting the basket 12 of the fuel transport container 10A.
It is a longitudinal cross-sectional view taken out. Basket hole element 1
Reference numeral 8 denotes a basket constituent member of the basket 12.

The fuel transport container 10 shown in this embodiment
In the figure, a substantially rectangular fuel pedestal 16 constituting a fuel support is independently installed at the bottom of the basket hole 45 of each basket hole element 18 of the basket 12. A fuel receiving portion 47 is recessed on the surface (upper surface) of the fuel receiving base 46, and the lower end portion of the rectangular tubular fuel body 11 is fitted and positioned on the fuel receiving portion 47, and is placed. The fuel support device 48 of the fuel body 11 is configured.

A ring-shaped, torus-shaped or skirt-shaped support leg 49 projects from the bottom surface (lower surface) of the fuel receiving base 46, and pressurized gas is supplied onto the bottom surface of the basket hole 45 surrounded by the support leg 49. A space 50 is formed. A gas supply hole 51 faces and opens in the pressurized gas supply space 50,
The gas supply hole 51 is connected to a gas supply source (not shown) via a gas supply pipe 52 to constitute a flotation device 53 for levitating the fuel receiving pedestal 46.

The levitation device 53 is provided in a fuel support device 48 of the fuel body 11. By operating the levitation device 53, a pressurized gas such as high-pressure air is supplied to the pressurized gas supply space 50, the fuel pedestal 46 is lifted, and the fuel body 11 accommodated in the basket hole 45 is moved to the fuel pedestal 46.
It is designed to be lifted slightly.

On the other hand, a driving device 55 for moving the fuel receiving pedestal 46 is provided independently for each basket hole on an extension of a diagonal line of the fuel receiving pedestal 46. The drive unit 55 includes a drive mechanism 56 such as a four-bar drive link mechanism. The drive mechanism 56 is driven by rotating the rotation shaft 57 to move the fuel receiving base 46 between the fuel body insertion / removal position and the offset position. It can be moved back and forth between them.

The drive device 55 and the fuel support device 48 having the levitation device 53 constitute a fuel biasing device 60. The biasing device 60 is a floating device 53 for the fuel body 11.
And the driving device 55 cooperate with each other, so that the lateral direction of the fuel receiving base 46 (the direction perpendicular to the direction in which the fuel body 11 is inserted).
The movement is performed smoothly and smoothly, and the lower part of the fuel body 11 is offset by the basket hole 45. In the transport container 10A for the reactor fuel, since the fuel biasing device 60 is provided in each basket hole element 18, each basket hole 4A is provided.
The lower part (tip part) of the fuel body 11 inserted in the 5 can be individually biased.

By operating the fuel securing device 23 almost simultaneously with the lowering of the fuel body 11, the fuel body 11 is pressed by the fastening plate 24 of the fuel securing device 23, and the side wall surface of the basket hole 45 is formed. It can be pressed and tightened and secured. Similar to the securing device shown in FIG. 2, a plurality of fuel securing devices 23 are provided on the outer wall adjacent to the basket hole element 18 at a plurality in the axial direction at intervals.

In the fuel transport container 10A, the shifting of the bottom of the fuel assembly 11 and the fastening of the fuel assembly 11 can be performed simultaneously or after the shifting, so that the securing can be performed more safely and with a high degree of freedom. The fuel body 11 can be aligned and secured. As a result, the problem of misalignment of the fuel body 11 can be solved, and a fuel transport container 10A that can achieve compactness, large capacity, and low transportation cost can be provided.

The loading of the fuel body 11 into the fuel transport container 10A is performed vertically.

Each basket hole 45 of the fuel transport container 10A
After the fuel body 11 is inserted into the pressurized gas supply space 50 on the lower surface of the fuel receiving base 45, the levitation device 53 is operated to supply a pressurized gas such as high-pressure air.
Levitate slightly with.

Since the pressurized gas is supplied by the operation of the levitation device 53, the driving device 55 is driven to
And move it horizontally. The driving of the driving device 55 moves the fuel receiving pedestal 46 from the fuel body insertion / removal position shown in FIG.
The lower part (tip) of 1 is brought into contact with the adjacent V-shaped inner wall surface of the basket hole 45.

Simultaneously with or after the displacement of the lower portion of the fuel body 11, the fuel securing device 23 is operated to
4 is projected into the basket hole 45. This fastening plate 24
, The fuel body 11 is biased over the entire length in the basket hole 45, and the adjacent V of the square tubular fuel body 11
The two sides of the V-shape abut the V-shaped inner wall surface adjacent to the basket hole 45, and the fuel plate 1 is fastened by the fastening plate 24 of the fuel securing device 23.
1 is tightened and secured. This fuel transport container 1
In the case of 0A, since the fuel unbalance device 60 and the fuel securing device 23 are provided for each basket hole 45, the securing can be performed simultaneously with or after the misalignment of the bottom of the fuel body 11 and the securing of the fuel body 11. Thus, the degree of freedom in handling the fuel body 11 can be improved.

[0069]

As described above, in the container for transporting nuclear fuel and the method for transporting the same according to the present invention, there is a problem of misalignment of the fuel body or the fuel protection container accommodated in the basket hole of the fuel transport container. Therefore, a fuel transport container capable of accommodating and transferring a large number of fuel bodies can be provided, and a large number of fuel bodies can be transported simultaneously in a compact fuel transport container, thereby reducing transportation costs. When the fuel body is stored directly in the basket hole of the fuel transport container,
The need for a fuel protection container is eliminated, so that more fuel can be efficiently stored in the fuel transport container, and a compact and large-capacity fuel transport container can be provided. It can be transported efficiently.

According to the first aspect of the present invention, the fuel body or the fuel protection container inserted into the basket hole is supported by the fuel biasing device to be biased, and secured in the basket hole by the fuel securing device. Therefore, the fuel body or the fuel protection container can be stably accommodated in the basket hole in a one-sided state and can be fixed, so that a compact and large-capacity fuel transport container can be provided.

According to the second aspect of the present invention, the fuel biasing device is composed of the fuel support device and the drive device of the support device, so that the fuel body or the fuel protection container inserted into the basket hole is used for the fuel support device. The fuel device or the fuel protection container can be moved by the driving device, and can be easily shifted.

According to the third and fourth aspects of the present invention, the fuel receiving stand (fuel receiving plate) supporting the front end of the fuel body or the fuel protection container inserted into the basket hole is lifted or lifted by the floating device or the slide support device. Since it is slidably supported, the movement of the fuel receiving pedestal can be performed smoothly and smoothly with a small driving force or operating force.

In the invention according to claim 5, all the fuel bodies or the front ends of all the fuel protection containers accommodated in the respective basket holes are supported by the pedestal of the fuel support device, and the fuel pedestal is mounted on the fuel biasing device. By moving with the drive device, all the fuel bodies or all the fuel protection containers can be moved at the same time, and can be efficiently biased.

In the invention according to claim 6, the fuel receiving pedestal is supported in the support receiving space via the levitating device or the slide supporting device, and the fuel receiving pedestal is held by the floating device or the slide supporting device so as to be levitated or slidable. The fuel pedestal can be moved with a small driving force because the fuel pedestal is moved with a small driving force, and the entire fuel assembly or the fuel protection container can be moved at the same time to more efficiently offset the fuel.

In the invention according to claim 7, since the fuel support device and the fuel biasing device provided with the driving device for moving the support device are provided for each basket hole, the fuel body or the fuel body inserted into the basket hole is provided. The fuel protection container can be individually biased for each basket hole by the fuel biasing device, and the degree of freedom of the biasing movement can be improved.

In the invention according to claim 8, since the fuel support device is supported via the levitation device or the slide support device, the drive device can move the fuel support device smoothly and smoothly with a small driving force. The one-sided operation of the fuel body or the fuel protection container can be performed more smoothly and smoothly.

According to the ninth aspect of the present invention, when the fuel transport container is placed in the horizontal position, the fuel body or the fuel protection device that is biased in the basket hole is connected to the V adjacent to the basket hole.
It can be supported by the two inner wall surfaces in the shape of a letter, and the support of the fuel body or the fuel protection container is stabilized, and the reliability can be improved. Further, since the fastening force of the fuel securing device may be small, the fuel securing device can be reduced in size and size, and accordingly, a compact and large-capacity fuel transport container can be provided.

According to the tenth aspect of the present invention, the tip of the fuel body or the fuel protection container inserted into the basket hole is shifted by the fuel shifter, and the fuel securing device shifts the tip end into the basket hole. Since the fuel is secured, the problem of misalignment of the fuel body or the fuel protection container is solved, and the fuel body or the fuel protection container can be stably housed in the basket hole, secured and secured in a one-sided state, and transferred. , Transfer reliability and stability can be improved.

According to the eleventh aspect of the present invention, in the fuel loading step, the tip of the fuel body or the fuel protection container inserted into each basket hole is supported by the fuel receiving pedestal, and the fuel receiving pedestal is driven by the driving device. Therefore, all the fuel bodies or the fuel protection containers inserted into the respective basket holes can be simultaneously shifted and moved efficiently and efficiently.

According to the twelfth aspect of the present invention, all the fuel bodies or all the fuel protection containers inserted in the respective basket holes are moved while supporting them so that they can float or slide at the same time. One-sided movement can be performed stably and smoothly with a small driving force, and the reliability of the one-sided movement can be improved.

According to the thirteenth aspect of the present invention, a fuel biasing device is provided for each basket hole, and can be individually biased and moved for each basket hole by the fuel biasing device. The degree of freedom of the one-sided movement can be kept large.

According to the fourteenth aspect of the present invention, since the fuel unit and the fuel protection container inserted into each basket hole are lifted or slidably supported and moved one-sided by the driving device, the fuel is inserted into each basket hole. The body or the fuel protection container can be smoothly and smoothly shifted with a small driving force, and the reliability of the shifting can be improved.

[0083] In the invention according to claim 15, the fuel body or the fuel protection container which is biased in the basket hole in the fuel transfer step can be supported by two V-shaped inner wall surfaces adjacent to the basket hole. Moreover, since the axis of the basket hole is inclined and installed so as to form an acute angle from the horizontal, the transfer support of the fuel body or the fuel protection container is stabilized,
Reliability can be improved. Further, the fastening force of the fuel securing device may be small, and the fuel securing device can be reduced in size and size. Therefore, a compact and large-capacity fuel transport container can be provided.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a basket, showing a first embodiment of a reactor fuel transport container according to the present invention.

FIG. 2 is a plan view of a basket provided in the reactor fuel transport container shown in FIG.

FIG. 3 is a perspective view of the reactor fuel transport container shown in FIG.
Sectional view along the line III.

FIG. 4 is a view showing a first embodiment of a nuclear reactor fuel transport container according to the present invention, in which a basket of the fuel transport container is viewed obliquely downward during fuel transport.

5 shows a cross section of the basket of the fuel transport container shown in FIG. 4 during fuel transport, and corresponds to FIG.

FIG. 6 is a longitudinal sectional view of a basket showing a modified example of the first embodiment of the nuclear fuel transport container according to the present invention.

FIG. 7 is a longitudinal sectional view of a basket hole element provided in the fuel transport container according to a second embodiment of the reactor fuel transport container according to the present invention.

8 is a plan view of the basket hole element shown in FIG.

[Explanation of symbols]

 10, 10A Fuel transport container 11 Fuel body 12 Basket 13 Basket body 14 Basket bottom plate (bottom cover) 15 Fuel receiving plate (Fuel support, Fuel receiving stand) 16 Support storage space 17 Fuel support device 18 Basket hole element 19 Connection Member 20 Basket hole (fuel storage chamber) 21 Fuel receiving part 23 Fuel securing device 24 Tightening plate 25 Connecting column 26 Connecting hole 27 Connecting device 29 Support leg 30 Pressurized gas supply space 31 Gas supply hole 32 Gas supply pipe 33 Levitation Device 35 Drive device 36 Drive mechanism 37 Rotating shaft 40 Fuel shift device 44 Slide support device 45 Basket hole 46 Fuel receiving table 47 Fuel receiving portion 48 Fuel support device 49 Support leg 50 Pressurized gas supply space 52 Gas supply pipe 53 Levitation device 55 drive device 56 drive mechanism 57 rotating shaft 60 fuel Biasing device

Claims (15)

[Claims] In a fuel transport container for storing and transporting a fuel body of a nuclear reactor fuel directly or indirectly in a basket for a fuel or a fuel protection container, the fuel body inserted in the basket hole is provided. The fuel protection device includes a fuel biasing device that supports the fuel protection container and moves in a direction perpendicular to the insertion direction to bias the fuel protection container, and a fuel securing device that secures the fuel body or the fuel protection container inserted into the basket hole. The fuel container according to claim 1, wherein the fuel biasing device is provided at a bottom of a basket or a bottom of a basket hole. 2. The fuel shifting device according to claim 1, wherein the fuel shifting device is configured to support a fuel body inserted into a basket hole or a tip of a fuel protection container, and move the supporting device in a direction orthogonal to a fuel body inserting direction. The transport container for a nuclear reactor fuel according to claim 1, further comprising a driving device that drives the reactor fuel. 3. The fuel support device according to claim 1, further comprising: a fuel receiving stand for supporting a tip of the fuel body or the fuel protection container inserted into the basket hole, and a flotation device utilizing pressurized gas for floating the receiving stand. A container for transporting nuclear fuel according to claim 2. 4. The fuel support device according to claim 1, wherein the fuel support unit supports a tip end of a fuel body or a fuel protection container inserted into a basket hole, and a roller for supporting the support base in a shiftable manner.
3. The transport container for nuclear reactor fuel according to claim 2, further comprising a slide support device such as a bearing. 5. A support storage space is formed between a basket main body having a plurality of basket holes formed therein and a basket bottom plate fixed to the bottom of the basket main body. A fuel support for mounting the tip of the container is provided to constitute a fuel support device, and a fuel biasing device is constituted by the fuel support device and the driving device. The fuel biasing device is inserted into a basket hole. 3. The container for transporting nuclear fuel according to claim 2, wherein all the fuel bodies or all of the fuel protection containers are simultaneously moved and biased. 6. The fuel support device includes a fuel receiving base installed in a support storage space via a flotation device using a pressurized gas or a slide support device, and the fuel shift device is inserted into a basket hole. 6. The reactor fuel transport according to claim 5, wherein all the fuel bodies or all the fuel protection containers are simultaneously lifted and shifted by a driving device while being simultaneously supported by a fuel support device so as to be able to levitate or shift. container. 7. A fuel receiver for mounting a fuel body or a tip of a fuel protection container is provided at a bottom of each basket hole of a basket, and a fuel support device is provided for each basket hole. Is provided in each basket hole by providing a drive device for moving the fuel assembly in a direction perpendicular to the direction of insertion of the fuel body. 3. The transport container for a nuclear reactor fuel according to claim 2, wherein the transport container is configured to be moved for each basket hole and offset. 8. The fuel support device includes a fuel receiving base installed at the bottom of each basket hole via a flotation device using a pressurized gas or a slide support device. 8. The container for transporting nuclear fuel according to claim 7, wherein the inserted fuel body or the fuel protective container is supported by the fuel supporting device so as to be levitated or shiftable, and is moved by the driving device to be biased. 9. The basket hole of the basket and the fuel body or the fuel protection container are formed in a rectangular tube shape, and when the fuel transport container is set in a horizontal position, the basket comes into contact with the offset fuel body or the fuel protection container. Two inner wall surfaces adjacent to the hole are located below the fuel body or the fuel protection container, and the inner wall of the basket hole is inclined at an acute angle from horizontal, and the fuel body or the fuel protection container has a V-shaped cross section. 9. The basket according to claim 1, wherein the basket is supported by an inner wall surface.
A transport container for a nuclear reactor fuel according to any one of the above. 10. A step of setting a fuel transport container in a vertical position to load a fuel body of a reactor fuel, and placing the fuel transport container in a horizontal position from each fuel facility to a nuclear power plant or another fuel facility. In the method for transporting nuclear fuel having a transferring step, in the fuel loading step, after directly inserting the fuel body of the nuclear fuel into the basket hole of the fuel transport container or indirectly by putting it in the fuel protection container, While the tip of the fuel body or the fuel protection container is moved by the fuel biasing device to perform the biasing, the fuel body or the fuel protection container which is biased by the fuel securing device is secured in the basket hole, and the fuel body is secured. Alternatively, a method for transporting nuclear fuel, wherein a fuel protection container is loaded in a basket hole. 11. In the fuel loading step, all the fuel bodies or the front ends of all the fuel protection containers inserted into the respective basket holes of the fuel transport container are supported by a fuel cradle of a fuel support device. 11. The nuclear reactor according to claim 10, wherein all the fuel bodies or all the fuel protection containers are simultaneously shifted by being driven by the driving device, and after the one-sided movement, the fuel body or the fuel protection container is secured by the fuel securing device. How to transport fuel. 12. In the fuel loading step, all the fuel bodies or the front ends of all the fuel protection containers inserted into the respective basket holes of the fuel transport container are supported by a fuel cradle of a fuel support device, and the fuel cradle is mounted on the fuel cradle. While the levitation device or the slide support device using the pressurized gas is used to float or slide, the driving device drives the fuel cradle to float or slide all the fuel bodies or all the fuel protection containers at the same time, and at the same time to offset them. The method for transporting nuclear reactor fuel according to claim 11, wherein: 13. In the fuel loading step, the tip of the fuel body or the fuel protection container inserted into the fuel receiving container provided at the bottom of each basket hole of the fuel transport container is supported and inserted into the basket hole. The fuel body or the fuel protection container is moved individually by the fuel biasing device provided for each basket hole, and subsequently or simultaneously with the biasing, the fuel securing device is protected by the fuel securing device. 11. The container is secured in the basket hole.
3. The method for transporting nuclear reactor fuel according to item 1. 14. In the fuel loading step, a tip of a fuel body or a fuel protection container is supported by a fuel receiver of a fuel support device installed in each basket hole of a fuel transport container, and the fuel receiver is added. A fuel device or a fuel protection container is lifted or slid by a driving device while a levitation device or a slide support device using a pressurized gas or a slide support device is used to float or slide, and the fuel inserted into each basket hole is driven. 14. The method for transporting nuclear fuel according to claim 13, wherein the body or the fuel protection container is individually biased. 15. In the fuel transfer step, two inner wall surfaces adjacent to the basket hole which is in contact with the fuel body or the fuel protection container which is offset in the basket hole are positioned below the fuel body or the fuel protection container. And the inner wall of the basket hole is installed so as to be inclined at an acute angle from the horizontal, and the fuel body or the fuel protection container is transferred while being supported by two adjacent inner surfaces of the basket hole having a V-shaped cross section. A method for transporting nuclear fuel according to the above.