WO2020193910A1

WO2020193910A1 - Storage container of interchangeable configuration for a cask for transporting and/or warehousing radioactive materials

Info

Publication number: WO2020193910A1
Application number: PCT/FR2020/050558
Authority: WO
Inventors: Fabien LE STUM; Pierre Teyssier; Benjamin Kerr
Original assignee: Tn International
Priority date: 2019-03-28
Filing date: 2020-03-16
Publication date: 2020-10-01
Also published as: FR3094548B1; FR3094548A1

Abstract

The invention relates to a storage container (1) of interchangeable configuration, the container being intended to be housed in a cask (200) for transporting and/or warehousing radioactive materials, and comprising, in the longitudinal direction (8), a plurality of successive transverse structures (20), the transverse structures (20) being provided in a number N corresponding to an integer greater than or equal to three, and the container being produced by alternation of structural stages (ESi) and of stages (EEi) spacing apart the structural stages, each spacing stage (EEi) being formed by a plurality of longitudinal spacing devices (30), each comprising at least one elementary spacing member (32a, 32b), at least one elementary spacing member (32a) of one of the spacing stages (EEi) having a height (H1) different from the height (H2) of at least one elementary spacing member (32b) of another spacing stage (EEi).

Description

DESCRIPTION

TITLE: STORAGE BASKET WITH INTERCHANGEABLE CONFIGURATION FOR

TRANSPORT AND / OR STORAGE PACKAGING OF RADIOACTIVE MATERIALS

TECHNICAL AREA

The present invention relates to the field of transport and / or storage of radioactive materials, for example spent cluster guides from a nuclear reactor, or else irradiated fuel assemblies.

The invention relates more particularly to a storage basket intended to receive these radioactive materials. Such a basket is known to be placed in the cavity of a transport and / or storage packaging, this cavity forming a containment enclosure for radioactive materials.

STATE OF THE PRIOR ART

From the prior art, many designs of radioactive material storage baskets are known. These designs can be based, for example, on the use of stacked transverse cakes. Another known design resides in the use of stacked and intersecting structures. In all cases, the components of the basket define longitudinal housings, usually parallel, in which the radioactive materials are housed. This allows the basket to fulfill one of its primary functions, namely to retain radioactive material in the cavity of the package.

Each basket is designed to receive a given type of radioactive material, with precise dimensions and intrinsic characteristics. Therefore, to accommodate another type of radioactive material, it is usually necessary to have a basket of different geometry. These constraints thus remain all the higher as there are radioactive materials of different types.

By way of example, for baskets intended to house cluster guides, there is generally provided within this basket a transverse support structure for these cluster guides. This transverse support structure for the cluster guides is intended to serve as a stop for the junction between the lower part and the upper part of the guides, so that the latter rest by gravity in the basket, on this same transverse support structure. Generally, the height of the basket under the transverse guide support structure is adapted to the length of the lower part of these guides. With such an embodiment, it is generally not conceivable to accommodate cluster guides of different designs, in particular when the junction between their lower and upper parts is at a different location from that of the guides for which the basket was initially. designed. Indeed, this could lead to unwanted support of the guides in the bottom of the basket or of the packaging instead of obtaining their suspension on the transverse support structure, and / or cause the upper part of these guides to protrude from the bottom. - beyond the basket, upwards. In both cases, the transport and / or storage of these guides of different designs could not be considered with the same basket. Another storage basket, of a different design and adapted to that of these cluster guides, would thus be required.

This problem is encountered in many other circumstances, for example when the basket also fulfills a radiological protection function, and the dedicated structures must be located in line with the zone of the radioactive materials which generate the most radiation. This high radiation area can vary from one type of radioactive material to another, so baskets of different designs are needed. The same applies when the basket fulfills a thermal transfer function to the packaging, and / or a mechanical resistance function aimed at distributing the transverse forces as best as possible on the basket housings, as a function of the mass distribution of the radioactive materials. in these accommodations. DISCLOSURE OF THE INVENTION

To respond to the problem identified above, the invention relates to a storage basket with interchangeable configuration, the basket being intended to be housed in a packaging for transporting and / or storing radioactive materials, and intended to receive at at least one longitudinal radioactive assembly extending parallel to a longitudinal direction of the basket, the basket comprising a plurality of transverse structures following one another in the longitudinal direction and comprising, at least for some of them, at least one orifice intended to be traversed by the at least one longitudinal radioactive assembly, the transverse structures being provided in a number N corresponding to an integer greater than or equal to three, the basket being produced by the alternation, in the longitudinal direction of the basket, of structural stages and of spacing stages of the structural stages, each structural stage being formed by one of the transverse structures or by a stack of transverse structures in contact with one another, and each spacing stage being formed by a plurality of longitudinal spacing devices each comprising at least one elementary member d 'spacing, the basket being such that at least one elementary spacing member of one of the spacing stages has a height r different from the height of at least one elementary spacing member of another spacing stage.

Thus, the invention has a modularity which enables it to adopt several distinct configurations, to be chosen according to the radioactive materials to be transported and / or to be stored. In particular, provision is made for at least one elementary spacing member of one of the spacing stages to have a height different from the height of at least one elementary spacing member of another spacing stage. . This makes it possible to arrange the transverse structures in a particular way along the longitudinal direction of the basket, to achieve the desired design. Advantageously, the displacement of all or part of these elementary members of different heights easily leads to obtaining a basket having another configuration, provided for another type of radioactive material. More generally, the size and the number of elementary spacers can be adapted between each set of two directly consecutive transverse structures, so that they adopt a precise and adjustable position according to the longitudinal direction of the basket. .

Therefore, a basket parts kit can allow for the realization of separate and interchangeable designs, selected based on one or more criteria such as form of the radioactive materials to be housed, their maximum radiation zone, their maximum heat zone, or even their mass distribution.

The kit then advantageously benefits from a very broad spectrum of use, compared to a conventional basket generally suitable for housing a single type of radioactive material.

The invention also has at least one of the following optional characteristics, taken individually or in combination.

The basket comprises at least two spacing stages each having a plurality of longitudinal spacing devices each comprising a single elementary spacing member, the single elementary member of one of the two spacing stages having a height different from the height of the single elementary member of the other spacing stage. Alternatively, within the spacing devices concerned, the elementary members of different heights could be provided in association with other elementary members, so that they succeed each other in the longitudinal direction of the basket, without leaving the frame of the invention.

At least one spacing stage comprises a plurality of longitudinal spacing devices, each comprising at least two elementary spacing members following one another in the longitudinal direction. This advantageously makes it possible to further increase the modularity of the basket.

Each spacing stage includes at least two longitudinal spacers.

At least one spacing stage is formed by longitudinal spacing devices each comprising at least two elementary spacing members of different heights and following one another in the longitudinal direction.

Each spacing device takes the form of a column or a pillar, solid or hollow. Preferably, the columns / pillars are aligned so as to form a plurality of extended columns / pillars each extending the full height of the basket between the two opposite transverse end structures of the basket, and each being interrupted by the transverse structures arranged between the transverse end structures of the basket. These alignments allow a longitudinal continuity beneficial for the absorption of mechanical forces. However, the columns / pillars could not be aligned from one spacing floor to another directly consecutive spacing floor, without departing from the scope of the invention.

At least one of the extended columns / one of the extended pillars is crossed by a tie rod. This configuration facilitates the assembly of the basket.

Each elementary spacing member has a height greater than or equal to 1 cm.

Each transverse structure is made in one piece, or by assembling several elements, for example stacked and crisscrossed.

The basket has longitudinal liners passing through the transverse structures and defining housings for the longitudinal radioactive assemblies. Alternatively, the housings can be defined directly by the orifices of the transverse structures of the basket, without departing from the scope of the invention.

Preferably, at least one of the spacing stages, and even more preferably several or even each of these spacing stages, is formed by a plurality of independent longitudinal spacing devices, spaced transversely from one another. By being independent, these devices form discrete entities, not connected to each other, and which can therefore be mounted successively or simultaneously on the transverse structure 20 which is directly below them in the stack of parts of the basket. Alternatively, the devices of the same spacing stage could be wholly or partly connected to each other, in particular to facilitate their handling during assembly / disassembly of the basket, without departing from the scope of the invention.

The subject of the invention is also an assembly comprising a packaging for the transport and / or storage of radioactive materials defining a housing cavity, as well as a storage basket as described above, housed in said cavity.

The subject of the invention is also a package comprising such an assembly, as well as longitudinal radioactive assemblies housed in the storage basket.

Finally, the invention relates to a method for changing the configuration of a storage basket, starting from a basket according to the invention and having a first basket configuration in which at least one elementary spacer member of a given spacer stage has a height different from the height of at least one elementary spacer of another spacer stage, the method comprising the modification of the basket according to the first configuration so as to move at least one of the elementary spacing members of each of the spacing devices of the given stage, to a spacing stage different from said given spacing stage, in order to result in a basket according to the invention and having a second basket configuration distinct from the first. Of course, this change in configuration may also involve the displacement of other elementary spacing members, without departing from the scope of the invention.

Other advantages and characteristics of the invention will appear in the detailed non-limiting description below.

BRIEF DESCRIPTION OF THE DRAWINGS

This description will be made with reference to the accompanying drawings, among which;

[Fig. 1] shows a schematic view in longitudinal axial section of a package comprising a packaging for the storage and / or transport of radioactive materials, housing a storage basket according to the invention;

[Fig. 2] shows a schematic view in longitudinal axial section of the basket, according to a first preferred embodiment and adopting a first configuration;

[Fig. 2a] shows a view similar to the previous one, with the basket taking the form of an alternative embodiment;

[Fig. 3] shows a perspective view of a transverse structure fitted to the basket of the previous figure, the structure being in a first embodiment;

[Fig. 3a] shows a perspective view of a transverse structure fitted to the basket of the previous figure, the structure being in a second embodiment; [Fig. 4] shows a perspective view of an elementary spacing member fitted to the basket of the previous figure, the structure being in a first embodiment; [Fig. 5] shows a perspective view of an elementary spacer member according to a second embodiment;

[Fig. 6] shows a view similar to that of Figure 2, with the basket being in a second configuration;

[Fig. 7] shows a view similar to that of Figure 2, with the basket being in another second configuration;

[Fig. 8] shows a schematic view in longitudinal axial section of the basket, according to a second preferred embodiment and adopting a first configuration;

[Fig. 9] shows a view similar to that of FIG. 8, with the basket having a second configuration;

[Fig. 10] shows a schematic view in longitudinal axial section of the basket, according to a third preferred embodiment and adopting a first configuration;

[Fig. 11] shows a view similar to that of FIG. 10, with the basket having a second configuration;

[Fig. 12] shows a schematic view in longitudinal axial section of the basket, according to a fourth preferred embodiment and adopting a first configuration;

[Fig. 13] shows a view similar to that of Figure 12, with the basket being in a second configuration;

[Fig. 14] shows a schematic view in longitudinal axial section of the basket, according to a fifth preferred embodiment and adopting a first configuration;

[Fig. 15] shows a view similar to that of Figure 14, with the basket being in a second configuration.

DETAILED PRESENTATION OF PREFERRED EMBODIMENTS

Referring firstly to FIG. 1, there is shown a package 100 comprising a packaging 200 for transporting and / or storing radioactive materials defining a housing cavity 2, as well as a storage basket 1 housed in this. cavity.

The packaging 200 is shown in a vertical storage position, in which its longitudinal axis 4 is oriented vertically. It is the same for the storage basket 1, sharing the same longitudinal axis 4. This is parallel to the longitudinal direction. or direction of the height of the basket and of the packaging, shown diagrammatically by the arrow 8. The packaging 200 comprises a packaging bottom 5 opposite to a removable cover 6 in direction 8. In addition to the bottom 5 and the cover 6 spaced from one another along axis 4, the package 200 comprises a lateral body 10 extending around this axis 4. During transport, the opposite axial ends of the lateral body 10 may be covered by covers shock absorbers 11, shown in dotted lines in Figure 1.

The bottom 5 and the cover 6 axially delimit a housing cavity 12 within which the basket 1 is received, itself receiving longitudinal radioactive assemblies 13. By way of examples, these longitudinal assemblies 13 can be cluster guides. spent from a nuclear reactor, also called cluster guide tubes (TGG), or irradiated or fresh fuel assemblies or even quivers of radioactive waste. In the embodiments shown, the basket 1 allows the housing of several longitudinal assemblies 13, but it could alternatively be designed to receive only a single assembly 13, without departing from the scope of the invention. When the longitudinal assemblies 13 are held by the basket 1 in the cavity 12 as shown diagrammatically in FIG. 1, they form with the packaging 200 the aforementioned package 100. The housing cavity 12 is also delimited laterally by the lateral body 10.

Conventionally, the cavity 12 of the packaging 200 forms a sealed containment enclosure for the longitudinal assemblies 13, unlike the basket 1 which will be described below, and whose housings which it defines for holding the assemblies 13 are generally open in the cavity 12. The lateral body 10 of the packaging 200 is usually provided to fulfill, in addition to a function of mechanical resistance, a function of radiological protection as well as a function of heat transfer radially outwards. .

Figure 2 shows basket 1 in more detail. It is in the form of a first preferred embodiment of the invention. One of the particularities of the invention lies in the fact that the basket 1 has a modular design, namely that it can easily change configurations, and this while maintaining the same height adapted to the housing cavity of the packaging. . The basket 1, with interchangeable configuration, is shown in a first configuration in this figure 2. Its design is based on the alternation, in the direction of the height 8, of structural floors referenced ESi, and spacing floors referenced EEi used to space the structural floors ESi. The design of the basket makes it possible to climb the floors one by one, starting from the bottom or from the head. In this first preferred embodiment, the stages ESi, EEi are simply stacked on top of one another in direction 8, then held together by fixing means which will be described below.

The stages ESi, EEi may have identical or different heights, even if preferably at least two of the spacing stages EEi have two different heights.

In this first embodiment, the basket according to the first configuration comprises five structural stages ES1-ES5, arranged alternately with four spacing stages EE1-EE4. The number N of structural stages ESi may nevertheless vary, while remaining greater than or equal to three. In addition, the spacing stages EEi are, by design of the basket, provided in a number N-1.

The structural stages ESi are each formed by a transverse structure, or by a stack of transverse structures in contact with one another, that is to say not separated by spacing stages. In this first configuration of FIG. 2, each structural stage ESi is constituted by a single transverse structure 20, which extends in a plane substantially orthogonal to the longitudinal axis 4. According to a first embodiment shown in FIG. 3, the transverse structure 20 can be made in one piece, that is to say in one piece or in one piece, thus adopting the shape of a wafer whose thickness is typically between 1 and 15 cm. This shape is preferably adopted for the stages ES2-ES5 of the basket of FIG. 2. The alternative shown in FIG. 3a provides for a transverse structure 20 produced by assembling several elements, for example elements 22 stacked and intersecting. This shape is preferably adopted for the bottom stage ESI of the basket of FIG. 2, and its more substantial thickness is typically between 5 and 200 cm. In all cases, the transverse structures 20 have an external geometry of a shape complementary to that of the housing cavity of the packaging, here the general shape of a disc or cylinder of circular section. These structures 20 also have through orifices 24, intended to be crossed by the longitudinal radioactive assemblies 13 when the latter are loaded into the basket. Each structure 20 thus has a number of orifices 24 corresponding to the number of radioactive assemblies 13 to be loaded into the basket. These orifices 24 are provided on all the transverse structures 20 of the basket, except possibly on that of the bottom and / or on that of the head. As can be seen in FIG. 2, the orifices 24 of the various transverse structures 20 are aligned in groups so as to define housings for the radioactive assemblies 13, of complementary shape. Thus, the latter can be maintained directly in the orifices 24 at each structural stage ESi of the basket, as has been shown schematically with the assembly 13 on the left of FIG. 2. Alternatively, the orifices 24 can be used to hold liners 26. crossing the structural stages ESi and each extending over the entire height of the basket, or substantially over the entire height. In this case, it is the sleeve 26 itself which internally defines a housing 28 for receiving a radioactive assembly 13 of identical or substantially identical length, as has been shown diagrammatically with the assembly 13 on the right of the figure. 2.

In all cases, that is to say by direct or indirect maintenance via the orifices 24, the longitudinal radioactive assemblies 13 are arranged parallel to the direction 8 and to the longitudinal axis 4 of the basket.

The spacing stages EEi are for their part specific to the present invention, each being produced by a plurality of longitudinal spacers 30 preferably independent of one another, and preferably spaced transversely from one another. In the preferred case of an independence of the spacing devices 30, within each spacing stage EEi, these devices 30 form discrete entities, not connected to each other, and which can therefore be mounted successively or simultaneously on the transverse structure 20 which is directly below them in the stack of parts of the basket. The number of devices 30 per stage EEi is preferably greater than or equal to two, for example two, three, four, five or six. These devices 30 are preferably arranged at the periphery of the basket, preferably being regularly distributed circumferentially around the longitudinal axis 4.

Each spacing device 30 is formed by one or more elementary spacing members 32a, 32b succeeding each other in direction 8. When several follow one another, the members 32 are for example simply stacked on top of each other, that is to say superimposed in direction 8. They are preferably each made in one piece, taking the form of a hollow column as shown in FIG. 4, or else that of a hollow pillar as shown. in Figure 5. The sections of this column / pillar may nevertheless differ from those shown in Figures 4 and 5, without departing from the scope of the invention.

The hollow character of the elementary spacers 32a, 32b is not necessary, but here it allows the passage of fixing rods 40. In fact, each rod 40 comprises a bottom cooperating with the structure 20 forming the ESI stage and a threaded head cooperating with a tightening nut 41. The bottom and the head of the tie rod are connected by the rod of this tie rod which passes through all the stages of the basket. More precisely, each tie rod 40 passes through all the structural stages ESi, as well as each elementary member 32a, 32b of a spacer device 30 of each spacer stage EEi. In this regard, it is noted that the elementary members 32a, 32b are aligned in groups in direction 8, so as to form extended columns / extended pillars 44, each extending / each at least over the height of the basket between the two opposite end transverse structures of this basket. As can be seen in FIG. 2, these extended columns / pillars 44, crossed by the tie rods 40, are interrupted by the transverse structures 20 at the level of parts thereof having passages 46 allowing the crossing of the tie rods 40.

By applying a compressive force through the clamping nut 41, each tie rod 40 contributes to maintaining the stages EEi, ESi against each other. On the other hand, the formation of extended columns / pillars 44 ensure continuity in the absorption of the longitudinal forces flowing through the basket. In this first embodiment, only two distinct types of elementary spacers are used. These are organs 32a of the same height Hl, and members 32b of the same height H2 less than the height Hl. Other types of members could nevertheless equip the spacing devices 30, without departing from the scope of the invention. All the members 32a, 32b preferably have the same outside diameter.

The heights H1, H2 of the members 32a, 32b are preferably greater than or equal to 1 cm. Within the same spacing stage EEi, the devices 30 are all made with the same elementary member or with the same combination of elementary members, so that each spacing stage EEi has a uniform height between the elements. two transverse structures 20 arranged on either side.

The number and height of the elementary members 32a, 32b are chosen at each spacing stage EEi as a function of the desired position for each of the transverse structures 20, in the direction 8. In the first configuration of the basket, it is listed below. below, for each stage EEi, the number and type of elementary members per spacing device 30:

Stage EE1: a single organ 32b;

Floor EE2: two organs 32b stacked;

Stage EE3: a single unit 32a;

- Stage EE4: a single unit 32b.

This first configuration can be adopted to best suit one or more criteria of certain radioactive assemblies 13 to be housed in the basket, such as the shape of these assemblies 13, their maximum radiation zone, their maximum heat zone, or even their mass distribution.

When other radioactive assemblies have to be transported / stored in basket 1, the design of the latter can easily be changed so that the latter adopts a second configuration distinct from the first. The method for changing the configuration then consists, in general, in moving one or more elementary members 32a, 32b from one spacing stage to another, it being understood that this operation may concern one or more stages of the basket. The objective residing, as for the first configuration, to achieve a second configuration adapting to the better still one or more criteria of another type of radioactive assemblies 13 to be housed in the basket, such as the shape of these assemblies 13, their maximum radiation zone, their maximum heat zone, or even their mass distribution.

FIG. 6 represents the result of the implementation of such a method, specific to the invention, in which the elementary members 32a, 32b of the stages EE3 and EE4 have been inverted.

In the second configuration of the basket of FIG. 6, it is listed below, for each stage EEi, the number and type of elementary members per spacer device 30:

Stage EEI: a single organ 32b;

Floor EE2: two organs 32b stacked;

Stage EE3: a single unit 32b;

- Stage EE4: a single unit 32a.

It is noted that Figure 2a shows an alternative embodiment to that of Figure 2, in which a single elementary member 32a, 32b is provided within each spacing device 30 of each stage EEi, with at least two of these members having different heights Hl, H2.

FIG. 7 represents the result of the implementation of another method, aiming to move one of the two elementary spacing members 32b of each of the spacing devices 30 from the stage EE2, to the stage EEI so that the latter has for each of its own devices 30 two elementary members 32b stacked.

In this other second configuration of the basket of FIG. 7, it is listed below, for each stage EEi, the number and type of elementary members per spacer device 30:

Floor EE1: two organs 32b stacked;

Stage EE2: a single unit 32b;

Stage EE3: a single unit 32a;

- Stage EE4: a single unit 32b.

Many other configurations remain possible, simply by changing the arrangement of the elementary members 32a, 32b, and while obtaining the same total basket height regardless of the configuration adopted. This change is made easily, by loosening and then removing the nuts 41 screwed onto the heads of the tie rods 40, then axially dismantling the stages ESi, EEi one by one, in order to then re-stack them with the new distribution of the members 32a, 32b within the stages spacing EEi. Once this re-stacking has been completed, the nuts 41 can again be screwed onto the heads of the tie rods 40 and tightened to ensure the mechanical retention of the parts of the basket between them.

The invention is thus similar to a basket parts kit held by the operator, who can thus configure his basket according to the type of radioactive material to be housed, while always keeping, if desired, the same height. basket suitable for the same transport and / or storage packaging. It may nevertheless be necessary to add and / or remove basket parts while passing from one configuration to another, without departing from the scope of the invention.

FIG. 8 represents a basket 1 according to a second preferred embodiment, with this basket having a first configuration. It has six structural stages ES1-ES6, and five stages of spacing EE1-EE5. The latter are also produced using two types of elementary spacing members 32a, 32b, always of different heights Hl, H2.

The number and height of the elementary members 32a, 32b are chosen at each spacing stage EEi as a function of the desired position for each of the transverse structures 20. The structural stage ES3 here performs a shielding function, of the neutron shielding type and / or with respect to a gamma radiation emitted by the radioactive assemblies 13. Consequently, this structural stage of greater height than the other stages ESi, and produced by a single transverse structure 20 or by the stacking of several of them in contact with each other, is located in line with the maximum radiation zone 13a of the assemblies 13. By being able to adapt in this way the position of the shielding elements in relation to the maximum radiation zone of the radioactive assemblies 13 , also called active zone 13a, it is advantageously not necessary to provide shielding over the entire height of the basket.

In the first configuration of the basket shown in FIG. 8, it is listed below, for each stage EEi, the number and type of elementary organs by spacing device 30:

Stage EE1: a single unit 32a;

Stage EE2: a single unit 32a;

Floor EE3: two organs 32b stacked;

Stage EE4: a single unit 32a;

- Stage EE5: a single unit 32a.

When another type of assemblies 13 must be housed in the basket, with an active zone 13a placed differently in the direction 8, the elementary members 32a, 32b can be moved to adapt the longitudinal position of the shielding stage ES3.

In the example of Figure 9 showing a second configuration of the basket, one of the members 32b of each device 30 of the EE3 stage has been moved to stack on or under the member 32a of each device 30 of the 'floor EE2. The shielding stage ES3 is thus raised compared to the first configuration.

Similarly, when the transverse structures 20 are dedicated to the transmission of heat from the radioactive assemblies 13 to the packaging, and / or to provide a mechanical resistance function aimed at best distributing the transverse forces on the basket housings, these structures 20 must be arranged as best as possible in relation to the zone 13b with the most mass of these assemblies. This zone 13b is represented in FIG. 10 showing the basket according to a third preferred embodiment, and being presented according to a first configuration.

Basket 1 has seven structural stages ES1-ES7, and six stages of spacing EE1-EE6. The latter are also produced using two types of elementary spacing members 32a, 32b, always of different heights Hl, H2.

The number and height of the elementary members 32a, 32b are chosen at each stage of spacing EEi as a function of the position desired for each of the transverse structures 20, the functions of which have been described above.

Consequently, it is ensured that at least three structural stages ES3, ES4, ES5 are located in line with the most mass area 13b of the assemblies 13. By being able to adapt in this way the position of the heat transfer elements / of mechanical resistance to the most mass area 13b of the radioactive assemblies 13, it is not advantageously no need to provide these same elements over the entire height of the basket.

In the first configuration of the basket shown in FIG. 10, it is listed below, for each stage EEi, the number and type of elementary members per spacer device 30:

Stage EEI: a single organ 32a;

Stage EE2: a single unit 32a;

Floor EE3: two organs 32b stacked;

Floor EE4: two organs 32b stacked;

Floor EE5 two bodies 32b stacked;

- Stage EE6: a single unit 32a.

When another type of assemblies 13 must be housed in the basket, with a zone 13b with the highest mass placed differently in the direction 8 and / or on a different longitudinal extent, the elementary members 32a, 32b can be moved to adapt the longitudinal position of heat transfer / mechanical strength stages ES3-ES5. For example, these stages can be brought closer to each other when the bulkier zone 13b extends over a smaller longitudinal extent of the radioactive assemblies 13, as has been shown diagrammatically in FIG. 11 representing the basket according to a second configuration.

In this second configuration of the basket, one of the members 32b of each device 30 of each of the three stages EE3-ES5 has been moved to stack on or under the member 32a of each device 30 of the stage EE2, which now has four stacked organs. The heat transfer / mechanical resistance stages ES3-ES5 are thus raised and tightened compared to the first configuration.

The preferred embodiments described so far are more applicable to housing spent fuel assemblies in the basket. The fourth preferred embodiment shown in Figures 12 and 13 is preferably applied to the housing of cluster guides 13.

FIG. 12 represents the basket 1 according to a first configuration. It has five structural stages ES1-ES5, and four stages of spacing EE1-EE4. These last are also produced using two types of elementary spacing members 32a, 32b, still of different heights Hl, H2.

In this first configuration, particular attention is paid to the penultimate structural stage ES4, given that it is formed by a transverse structure 20 forming a support for the cluster guides 13. In fact, the latter are formed. usually characterized by the presence of an axial stop 50 between its lower part 13 "and its upper part 13 ', which may have different sections. The axial stop 50, for example in the form of a shoulder, is thus intended to come in stop on the upper surface of the transverse structure of the penultimate structural stage ES4, so that the guides 13 rest by gravity on this same structure 20. The position of the latter in direction 8 must be adapted so that the upper part 13 'of the guides 13 does not project upwardly outside the basket, and so that the lower part 13 "does not come into abutment on the bottom of the basket or on the bottom of the packaging.

The first configuration of the basket 1 is adapted to meet the previous conditions, in the context of housing a first type of cluster guides 13 shown in FIG. 12. In this first configuration, it is listed below, for each stage. EEi, the number and type of elementary members per spacing device 30:

Stage EEI: a single organ 32a;

Floor EE2: two organs 32a stacked;

- Stage EE3: a stack of a member 32a and two members 32b;

- Stage EE4: a single unit 32a.

For the housing of cluster guides 13 of a second type, having for example an axial stop 50 arranged differently along the direction 8, the basket can be brought into a second configuration shown in FIG. 13. To achieve this second configuration, one of the two members 32b of each device 30 of the EE3 stage has been moved to stack on or under the member 32a of each device 30 of the EE4 stage. The transverse support structure 20 of the penultimate structural stage ES4 is thus lowered compared to the first configuration. Finally, FIG. 14 represents a fifth preferred embodiment of the invention, in a first configuration comprising six structural stages ES1-ES6, and five spacing stages EE1-EE5. The latter are also produced using two types of elementary spacing members 32a, 32b, always of different heights Hl, H2. In the first configuration of the basket shown in FIG. 14, it is listed below, for each stage EEi, the number and type of elementary members per spacer device 30

Stage EE1: a single unit 32a

Stage EE2: a single organ 32a

Floor EE3: the succession of five organs 32b

Floor EE4: the succession of two organs 32b;

- Stage EE5: a single unit 32a.

The second configuration of this basket 1, shown in FIG. 15, shows that the change of configuration is not limited to an inversion of elementary members between the spacing stages EEi. Indeed, other parts can be added with respect to the first configuration, just as some parts of the latter can be removed, and not retained in another configuration. Therefore, not all kit parts are necessarily implemented in all possible basket configurations.

In the second configuration of FIG. 15, a new transverse structure 20 is added, to form an additional structural stage. Here, this new structure 20 replaces one of the five elementary members 32b of each device 30 of the stage EE3 of the first configuration.

Thus, in the second configuration of FIG. 15, the basket 1 has seven structural stages ES1-ES7, and six spacing stages EE1-EE6. It is listed below, for each stage EEi, the number and type of elementary members per spacing device 30:

Stage EEI: a single organ 32a;

Stage EE2: a single unit 32a;

Floor EE3: the succession of two organs 32b Floor EE4: the succession of two organs 32b;

Floor EE5: the succession of two organs 32b;

- Stage EE6: a single unit 32a.

This principle makes it possible in particular to modulate the number of stages EEi, ESi from one configuration to another, while maintaining an identical basket height.

Of course, various modifications can be made by those skilled in the art to the invention which has just been described, solely by way of nonlimiting examples and of which the scope defined by the appended claims. In particular, the various preferred embodiments can be combined with one another.

Claims

1. Storage basket (1) with interchangeable configuration, the basket being intended to be housed in a packaging (200) for transporting and / or storing radioactive materials, and intended to receive at least one longitudinal radioactive assembly (13) extending parallel to a longitudinal direction (8) of the basket, the basket comprising a plurality of transverse structures (20) succeeding each other in the longitudinal direction (8) and comprising, at least for some of them, at least one orifice (24) intended to be traversed by at least one longitudinal radioactive assembly (13), the transverse structures (20) being provided in a number N corresponding to an integer greater than or equal to three, the basket being produced by the alternation , according to the longitudinal direction of basket (8), of structural stages (ESi) and of stages (EEi) of spacing between the structural stages, each structural stage (ESi) being formed by one of the transverse structures (20) or by a stack of s transverse structures (20) in contact with each other, and each spacing stage (EEi) being formed by a plurality of longitudinal spacing devices (30) each comprising at least one elementary spacing member (32a, 32b) , the basket being such that at least one elementary spacing member (32a) of one of the spacing stages (EEi) has a height (Hl) different from the height (H2) of at least one elementary member spacing (32b) of another spacing stage (EEi).

2. Storage basket according to claim 1, characterized in that it comprises at least two spacing stages (EEi) each having a plurality of longitudinal spacing devices each comprising a single elementary spacing member (32a, 32b ), the single elementary member (32a) of one of the two spacing stages (EEi) having a height (Hl) different from the height (H2) of the single elementary member (32b) of the other stage spacing (EEi).

3. Storage basket according to claim 1 or claim 2, characterized in that at least one spacing stage (EEi) comprises a plurality of longitudinal spacing devices each comprising at least two elementary spacing members (32a , 32b) succeeding in the longitudinal direction (8).

4. Storage basket according to any one of the preceding claims, characterized in that at least one spacing stage (EEi) is formed by longitudinal spacing devices (30), each comprising at least two elementary members d 'spacing (32a, 32b) of different heights (Hl, H2) and succeeding each other in the longitudinal direction (8).

5. Storage basket according to any one of the preceding claims, characterized in that each spacing device (EEi) takes the form of a column or a pillar, solid or hollow.

6. Storage basket according to the preceding claim, characterized in that the columns / pillars are aligned so as to form a plurality of extended columns / extended pillars (44) each extending over the entire height of the basket between the two. opposite end transverse structures of the basket, and each being interrupted by the transverse structures (ESi) arranged between the transverse end structures of the basket.

7. Storage basket according to the preceding claim, characterized in that at least one of the extended columns / one of the extended pillars (44) is crossed (e) by a fixing tie rod (40).

8. Storage basket according to any one of the preceding claims, characterized in that each elementary spacing member (32a, 32b) has a height (Hl, H2) greater than or equal to 1 cm.

9. Storage basket according to any one of the preceding claims, characterized in that each transverse structure (20) is made in one piece, or by assembling several elements (22), for example stacked and intersecting.

10. Storage basket according to any one of the preceding claims, characterized in that it comprises longitudinal liners (26) passing through the transverse structures (20) and defining housings (28) for the longitudinal radioactive assemblies (13).

11. Storage basket according to any one of the preceding claims, characterized in that at least one of the spacing stages (EEi) is formed by a plurality of independent longitudinal spacing devices (30), spaced transversely. one another.

12. An assembly comprising a packaging (200) for transport and / or storage of radioactive materials defining a housing cavity (12), as well as a storage basket (1) according to any one of the preceding claims, housed in said cavity (12).

13. Package (100) comprising an assembly according to the preceding claim, as well as longitudinal radioactive assemblies (13) housed in the storage basket (1).

14. A method of changing the configuration of a storage basket, starting from a basket (1) according to any one of claims 1 to 11 and having a first basket configuration in which at least one elementary member d the spacing (32a) of a given spacing stage (EEi) has a height (Hl) different from the height (H2) of at least one elementary spacing member (32b) of another spacing stage (EEi), the method comprising modifying the basket according to the first configuration so as to move at least one of the elementary spacers (32a, 32b) of each of the spacers (30) of the given floor (EEi), to a spacing stage (EEi) different from said given spacing stage, in order to result in a basket (1) according to any one of claims 1 to 12 and having a second basket configuration distinct from the first.