EP4136660A1

EP4136660A1 - Storage device for storing and/or transporting nuclear fuel assemblies, having a low-cost design

Info

Publication number: EP4136660A1
Application number: EP21723882.3A
Authority: EP
Inventors: Marcel TARDY; Stéphane NALLET
Original assignee: Orano Nuclear Packages and Services SAS
Current assignee: Orano Nuclear Packages and Services SAS
Priority date: 2020-04-14
Filing date: 2021-04-08
Publication date: 2023-02-22
Also published as: JP2023521216A; FR3109240A1; KR20230002520A; US20230127068A1; FR3109240B1; CN115605962A; WO2021209700A1

Abstract

The invention relates to a storage device (1) for transporting and/or storing nuclear fuel assemblies (2), intended to be accommodated in the cavity of a package for transporting and/or storing nuclear fuel assemblies, and comprising adjacent recesses (4, 4'), the device comprising a plurality of transverse structures (11) spaced apart by means of spacers (16), and sleeves (9) each passing through an opening (13) of at least one of the transverse structures (11), each sleeve (9) being made from flat bars (14a, 14b). According to the invention, in at least one transverse plane of the device passing through the sleeves, at least one of these sleeves has an inner recess-delimiting surface (10) formed in part by: - an inner surface (14a') of a first flat bar (14a) made with boron; and - an inner surface (14b') of a second flat bar (14b) made without boron.

Description

DESCRIPTION

TITLE: STORAGE DEVICE FOR THE STORAGE AND / OR TRANSPORT OF NUCLEAR FUEL ASSEMBLIES, WITH A LOW COST DESIGN

TECHNICAL AREA

The present invention relates to the field of transport and / or storage of nuclear fuel assemblies, preferably spent assemblies in which the fuel has been irradiated.

STATE OF THE PRIOR ART

Such a device, also called a storage “basket” or “rack”, comprises a plurality of adjacent housings each capable of receiving a nuclear fuel assembly.

This storage device, intended to be housed in a cavity of a package, is designed so as to be able to simultaneously fulfill three essential functions, which will be briefly explained below.

This is first of all the thermal transfer function of the heat released by the fuel assemblies. Generally, aluminum or one of its alloys is used, due to its good thermal conduction properties.

The second function concerns neutron absorption, and the concern to maintain the sub-criticality of the storage device when the latter is loaded with the fuel assemblies. This is achieved by using neutron absorber materials known as neutron absorbing materials, such as boron.

Finally, the third essential function relates to the mechanical strength of the device. It is noted that the overall mechanical strength of the device must be compatible with the regulatory safety requirements for the transport / storage of nuclear materials, in particular with regard to the so-called “free fall” tests.

From the prior art, several ways of forming the basket are known. One of them is to provide transverse structures, such as pancakes, spaced apart others by spacers, in the longitudinal direction of the basket. In addition, longitudinally oriented liners pass through the transverse structures, and each form a housing for receiving a nuclear fuel assembly.

The shirts are formed using successive flats in the circumferential direction of the shirt. These dishes can all be made using the same aluminum-based material, comprising a certain density of boron in order to fulfill the function of neutron absorption, and to achieve the desired effective multiplication factor "Keff". .

However, the production of such dishes with boron turns out to be particularly expensive, strongly impacting the overall production cost of the storage device.

DISCLOSURE OF THE INVENTION

The aim of the invention is therefore to remedy the drawback mentioned above, relating to the embodiments of the prior art.

To do this, the invention relates to a storage device for the transport and / or storage of nuclear fuel assemblies, the storage device being intended to be housed in the cavity of a packaging for transport and / or the storage of nuclear fuel assemblies, and comprising a number N of adjacent housings, each intended to receive a nuclear fuel assembly, the storage device comprising a plurality of transverse structures spaced from each other in a longitudinal direction of the storage device, using a plurality of spacers arranged between these transverse structures, the storage device also comprising sleeves respectively forming the N adjacent housings, each sleeve passing through an opening of at least one of the plurality of transverse structures, and preferably at least several of them, each jacket being produced by successive plates in a peripheral direction of the liner, each flat being arranged parallel or substantially parallel to a longitudinal axis of the housing defined internally by the liner. According to the invention, in at least one transverse plane of the storage device crossing the N shirts, and preferably in several distinct transverse planes, at the at least one of these liners, and preferably each of at least a plurality of liners among these N liners, has an interior housing delimiting surface formed in part by:

- an interior surface of a first plate made with boron; and

- an interior surface of a second dish produced without boron.

The originality of the invention lies in the heterogeneity of the plates forming the same jacket delimiting a housing intended to receive a nuclear fuel assembly, in particular by providing at least one second plate produced without boron. This principle results from an unexpected observation. Indeed, the manufacturing cost turns out to be greatly reduced when the jacket is made with non-borated dishes and with other dishes having a certain boron content, in comparison with a conventional solution resulting in the same effective multiplication factor. , and where all the dishes contain boron in a content lower than the aforesaid certain boron content. In other words, the invention provides for combining non-borated dishes and borated dishes with a boron content greater than the homogeneous content provided in a solution with equivalent performance of the prior art.

This principle advantageously contributes to reducing the production costs of storage devices, while exhibiting high performance from a criticality point of view. The invention also provides at least one of the following optional characteristics, taken individually or in combination.

In a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N liners, at least 30% of the N liners each have an interior housing boundary surface formed in part by:

- an interior surface of a first plate made with boron; and

- an interior surface of a second dish produced without boron.

Even more preferably, this characteristic, like all the essential and optional characteristics of the invention, is preferably observed in all the transverse planes of the storage device which pass through the shirts, or substantially in all these planes. Preferably, the N liners are distributed in liners delimiting peripheral housings and liners delimiting interior housings, and in a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N shirts, at least 50% of the liners delimiting peripheral housings each have an internal housing delimiting surface formed in part by:

- an interior surface of a first plate made with boron; and

- an interior surface of a second dish produced without boron.

Preferably, in a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N shirts, at least one of these shirts, and preferably each of a plurality of shirts among these N shirts , has an internal housing delimiting surface of generally square or rectangular section, and formed by:

- an interior surface of a first plate made with boron;

- an interior surface of a second dish produced without boron; and

- Two other dishes, and the first dish, the second dish and the other two dishes respectively form the four sides of the interior surface of the housing delimiting section of generally square or rectangular shape.

Preferably, said two other flats are formed respectively by:

- two first dishes made with boron; Where

- two second dishes made without boron; Where

- a first dish made with boron and a second dish made without boron.

Preferably, the plates forming the N liners are either first plates produced with boron, preferably with the same boron content, or second plates produced without boron.

Preferably, at least a first plate is made in one piece, preferably in an aluminum alloy comprising boron, and / or at least a first plate is provided with a coating comprising boron, preferably applied to an alloy material. aluminum. Preferably, at least a second plate is made of an aluminum alloy devoid of boron.

Preferably, the shirts each extend over the entire height of the storage device or over substantially all of this height, with each dish extending continuously over the entire height of the storage device or over substantially all of this height, or else by being sectioned longitudinally in order to form adjacent longitudinal sections of the liner. When the flats are sectioned, the longitudinal sections forming the same flat preferably all have the same boron content, or else are all boron-free. Alternative solutions exist, such as providing within the same flat several longitudinal sections having different boron contents, and / or providing within the same flat several longitudinal sections, some of which have boron, and of which others do not.

Be that as it may, the boron content in the first dishes very preferably remains constant within the entire storage device, for reasons of cost.

Preferably, in the sectioned design, at least one of the longitudinal liner sections bears axially on one of the transverse structures of the storage device.

Preferably, the transverse structures are wafers each pierced with N openings for receiving the N liners, respectively, the wafers preferably being made without boron.

Preferably, the storage device comprises tie rods for mechanically maintaining the stack of transverse structures and spacers in the longitudinal direction.

Preferably, the number of transverse structures, longitudinally spaced from one another, is greater than five, and preferably greater than ten.

A subject of the invention is also a packaging for the storage and / or transport of nuclear fuel assemblies, the packaging comprising a cavity in which is housed a storage device as described above. Finally, a subject of the invention is a package comprising such a packaging, as well as nuclear fuel assemblies arranged in the adjacent housings of the storage device of this packaging.

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 sectional view of a package according to the invention, comprising in particular a storage device for the storage and / or transport of nuclear fuel assemblies;

[Fig. 2] shows a partial perspective view of the storage device, according to a preferred embodiment of the present invention;

[Fig. 3] is a partial cross-sectional view taken along the transverse plane P of FIG. 2;

[Fig. 4] is a perspective view of one of the folders of the storage device shown in Figures 2 and 3;

[Fig. 5] is an enlarged partial view of that shown in FIG. 3;

[Fig. 6] shows an enlarged partial view similar to that of Figure 5, with the storage device being in the form of an alternative embodiment of the invention; and

[Fig. 7] shows a partial view in longitudinal section of the storage device in the form of another alternative embodiment of the invention.

DETAILED PRESENTATION OF PREFERRED EMBODIMENTS

Referring to Figure 1, there is shown a package 100 comprising a package 200 for the storage and / or transport of spent nuclear fuel assemblies 2. The package 200 has a body 202 formed by a lateral body 204, a bottom 206, and a removable cover 208. The bottom 206 and the cover 208 are spaced from one another along the longitudinal central axis 3 of the packaging, around which the lateral body 204 extends. The packaging 200 defines inside its body a cavity 210, in which is housed a storage device 1, which will be called “basket” in the remainder of the description. As will be detailed below, the basket 1 comprises a plurality of adjacent housings each intended to receive one of the nuclear fuel assemblies 2. When the basket 1 is housed in the cavity 210 of the packaging 200, and that the nuclear fuel assemblies 2 are placed in the adjacent housings of basket 1, package 100 is said to be "loaded".

As an indication, it is noted that at the axial ends of the packaging, the latter may have shock-absorbing covers 212, respectively covering the cover 208 and the bottom 206 of the body 202 of this packaging.

The particularity of the invention lies in the design of the basket 1 for transporting and / or storing spent nuclear fuel assemblies, which will now be described with reference first of all to FIGS. 2 to 5.

Basket 1 comprises a plurality of adjacent housings 4, 4 'arranged parallel to axis 3, the latter also corresponding to the longitudinal central axis of basket 1.

The number N of adjacent dwellings is here twenty-four, but this number could of course differ, for example by being between ten and one hundred.

The housings 4, 4 'are each suitable for receiving at least one fuel assembly 2 of square section, and preferably only one. As a result, they each have an internal housing delimiting surface 10, of cross section of generally square or rectangular shape. By "interior housing delimiting surface 10" is meant the surface of the basket elements which is located directly opposite the exterior surface of the fuel assemblies 2, as has been shown for one of them on figure 3.

The housings 4, 4 'are therefore provided so as to be juxtaposed to one another. They are each made by a sleeve 9, being provided according to the same number N. Each sleeve 9, parallel to the axis 3, extends over the entire height of the basket 1 in the longitudinal direction 20 of the latter, or substantially over all this height.

It is therefore the N sleeves 9 which form the N housings 4, 4 ′, among which a number NI of the peripheral housings 4 ′, as well as a number N2 of the housings interiors 4. Here, there are twelve peripheral housings 4 ', and twelve internal housings 4, but their numbers may of course differ, without departing from the scope of the invention. By “peripheral housings” is meant housings crossed by a fictitious peripheral line of the basket 1, and defining a closed peripheral row of housings 4 ', in which the internal housings 4 are circumscribed. Thus, the NI peripheral housings 4' are here divided into four peripheral segments of two housings 4 ', and into four housings 4' each defined by a sleeve 9 arranged between the ends of said peripheral segments.

The making of the N shirts 9 is specific to the present invention, and will be described in detail later.

To complete the design of the basket 1, the latter comprises a plurality of transverse structures 11, spaced apart from each other in the direction 20. The transverse structures 11 are planar or substantially planar structures, arranged orthogonally to the axis 3. In shape general disk or wafer, each of these structures 11 is pierced with N openings 13 for the reception respectively of the N liners 9. In other words, the same liner 9 successively passes through an opening 13 of each of the wafers 11 of the basket 1 .

The wafers 11 are for example made of steel or of a metal alloy, for example of an aluminum alloy, but whatever the material chosen, it is preferably free of boron or any other neutron absorbing element, that is, that is to say free from neutron absorber elements. The term “neutron absorber elements” is understood to mean elements which have an effective section greater than 100 barns for thermal neutrons. By way of indicative examples, these are aluminum alloys devoid of boron, gadolinium, hafnium, cadmium, indium, etc.

The number of wafers 11 is here preferably between fifteen and twenty-five, even if a different number could be adopted. These wafers are longitudinally spaced from one another by means of spacers 16, several of which are arranged between each pair of directly consecutive wafers 11 in the stack. For example, three to six spacers 16 are provided at each level of spacing between the wafers 11, the spacers of the same level having preferably all the same height in direction 20. The spacers 16 are preferably made of steel, but other materials can be considered, without departing from the scope of the invention.

The structure of the basket 1 is completed by tie rods 17 which hold the wafers 11 and the spacers 16 in compression against each other, in direction 20. The mechanical retention of the stack is thus ensured by the tie rods 17 which pass through them. wafers 11, and possibly also the spacers 16 by providing a hollow design for the latter. The number of tie rods 17 can then be identical to that of the spacers 16 provided at each level of spacing of the wafers, for example four spacers / tie rods in the embodiment shown in FIGS. 2 to 5. The tie rods 17, of known design , are preferably parallel to the axis 3, or substantially parallel to the latter.

Each of the N liners 9 is produced using four successive flats in the circumferential direction of the liner, these flats being arranged parallel in pairs and oriented parallel to axis 3, or substantially parallel to the latter. In other words, the four plates of the same liner 9 are oriented parallel or substantially parallel to a longitudinal axis (not shown) of the housing 4, 4 'defined internally by the liner.

As can be seen in FIG. 4 showing one of the liners 9 of the basket, the four plates 14a, 14b are provided with notches 22 at their longitudinal edges, so as to ensure mechanical strength by interlocking. Alternatively, the longitudinal edges of the plates 14a, 14b could for example be welded in pairs, without departing from the scope of the invention. These plates 14a, 14b here each extend continuously over the entire height of the basket, or substantially over this entire height.

More specifically with reference to Figure 3, it is noted that the design of all the liners 9 is not necessarily the same. In the preferred embodiment shown, some liners 9 forming the peripheral housings 4 'all have the same design, while other liners 9, forming the inner housings 4, also all have an identical design, distinct from that of the liners forming. the peripheral housings 4 '. This principle is only given as purely illustrative, and not limiting. Indeed, one of the peculiarities of the invention lies in the fact that each of a plurality of the N liners 9 is produced with at least one first flat 14a made with boron and of which an inner surface 14a 'forms part of the interior delimiting surface of the housing 10, and also with at least one second flat 14b produced without boron and of which an interior surface 14b ′ forms another part of this surface 10.

In the following description, preferably, all the first plates 14a are made of the same material, just as all the second plates 14b are made from the same material different from that of the first plates. As mentioned above, with regard to the first dishes 14a, they include boron. They are preferably made in one piece, in an aluminum alloy comprising boron. The boron can then be distributed homogeneously in the plate 14a, or in a heterogeneous manner. The boron content in the alloy is adapted according to several criteria such as the desired effective multiplication factor "Keff", the ratio between the number of first dishes 14a and the number of second dishes 14b, the position of the first dishes 14a at the within the basket, etc. As an indicative example, the boron content by mass can reach 16% or more in the alloy, but this value can also be lowered to only a few percent. Alternatively, instead of being in one piece, each first flat 14a could be a one-piece flat provided with a surface coating comprising boron. In this scenario, the one-piece plate could be made of an aluminum alloy, and the coating could be deposited according to any known techniques, such as for example the cold or hot spraying of boron carbide particles.

Preferably, the boron content is identical or substantially identical for all the first dishes 14a of the liners 9 of the basket 1.

As regards the second dishes 14b, they are free from boron. They are also free of any other neutron absorbing element, that is to say free of neutron absorber elements in the aforementioned sense. For these second plates 14b, they are also preferably made of an aluminum alloy, but therefore free of boron.

In this regard, it is noted that by "flat" is meant an element of generally planar shape, the thickness of which between its opposite surfaces is of a dimension smaller than each. dimensions in the other two directions orthogonal to the thickness direction, and orthogonal to each other. In addition, for each flat of a jacket 9, it can be a single flat element as shown in figure 5, or a superposition of several flat elements, in the direction of the thickness, as shown. in FIG. 6. According to yet another alternative, the flat can be a tubular element parallel to the axis 3, containing a flat element of complementary section. Each dish is preferably full or substantially full.

In the context of the invention, a judicious choice is therefore made between the first and the second plates 14a, 14b to produce each of the liners 9 of the basket 1. In general, the density of partitions produced from the first dishes 14a comprising boron is higher in the center of the basket, than at its periphery. Also, the liners 9 forming the peripheral housings 4 'are produced by combining first plates 14a comprising boron, and second plates 14b devoid of boron, preferably two of each. On the contrary, the liners 9 forming the interior housings 4 are produced only by first plates 14a comprising boron. However, some liners 9 forming the inner housings 4 could include one or more second flats 14b devoid of boron, just as some liners 9 forming the peripheral housings 4 'could only include second flats devoid of boron, without going beyond the scope of the liner. 'invention. Finally, for each jacket 9 formed by the association of first plates 14a comprising boron and second plates 14b without being free, the number of each of them and their relative arrangement can be adapted according to the needs and constraints encountered.

Returning to the preferred embodiment shown in Figures 2 to 5, in at least one transverse plane of the basket 1 such as the section plane P of Figures 3 and 5, and preferably in all of these transverse planes or substantially all of these planes transverse of the basket 1 passing through the liners 9, the interior housing delimiting surface 10 of the N2 interior housings 4 is formed by four first flats 14a provided with boron, using their respective interior surfaces 14a '.

In addition, still in the section plan (s) considered, the interior housing delimiting surface 10 of the NI peripheral housings 4 ′ is formed by the association of two first flats 14a, and two second flats 14b shown in solid lines in FIG. 3.

To further explain the design, reference will be made to the peripheral housing 4 'of Figure 5, in which the fuel assembly 2 has been partially shown. For this housing 4 ', in the transverse plane of the basket, its interior delimiting surface of the housing 10 consists of four sides, formed respectively by four straight segments. The first side of the interior surface 10 is formed by an interior surface 14b 'of a second plate 14b. The second side of the interior surface 10, adjacent to the first side, is also formed by an interior surface 14b 'of a second plate 14b. The third side of the interior surface 10, adjacent to the second side, is formed by an interior surface 14a 'of a first plate 14a. And finally, the fourth side of the inner surface 10, connecting the first and third sides, is also realized by an inner surface 14a 'of a first plate 14a.

Thus, even if all or part of the housings 4 arranged near or on the center of the basket 1 can be produced by liners obtained only from first plates 14a, those located more towards the periphery can result from an association between the first plates. and second dishes 14a, 14b.

In the example of the loaded housing 4 'of FIG. 5, there are therefore two second plates 14b devoid of boron, and two first plates 14a comprising boron. Alternatively, for these peripheral housings 4 'resulting from an association between plates of different types, it could be three second plates 14b devoid of boron, and a single first plate 14a comprising boron. In the first case, the dishes of the same nature could be directly consecutive and orthogonal in pairs, or else parallel in pairs. All these alternative designs can also be envisaged for the liners forming the interior housings 4, without departing from the scope of the invention.

Preferably, the association of plates 14a, 14b of different types concerns at least 30% of the N housings 4, 4 'of the basket, and at least 50% of the peripheral housings 4', even if in the mode shown, 100% of the peripheral slots 4 'are affected. Thanks to this association of plates 14a, 14b, some of which contain boron and others not, the manufacturing costs are reduced while obtaining high performance in terms of maintaining sub-criticality.

According to an alternative embodiment shown in FIG. 6, each flat of a shirt is formed by the superposition of two flat elements. Thus, each first flat 14a is obtained by the superposition of two flat elements 14a-a according to the direction of their thickness. In this case, it is the interior flat element which defines the interior surface 14a '. In addition, the two flat elements 14a-a may comprise boron, or only one of the two, that disposed towards the outside or that disposed towards the inside. In this case, one of the two flat elements 14a-14a can be made of steel, to reinforce the mechanical strength of the jacket 9.

A similar design can be provided for the second flats 14b, with the superposition of two flat elements 14b-a devoid of boron, one of which is for example made of steel. Nevertheless, a / more second dishes 14b devoid of boron can be provided in the form of single dishes, in cooperation with one / more first dishes 14a formed by the superposition of two flat elements 14a-a. The latter solution is for example obtained by starting with a jacket free of boron, for example made of steel, and on which one or more flat elements of the jacket are covered internally or externally with a flat element 14a-a provided with boron. In this embodiment, the liner in question can be made in a single piece forming successive plates in the peripheral direction of the liner, or with the aid of plates assembled to each other in successive following this same direction. direction.

Yet another alternative embodiment is shown in Figure 7, this embodiment being combinable with that of Figure 6.

In this other embodiment of FIG. 7, the flats 14a, 14b and the liners 9 which they form are no longer continuous longitudinally all along the basket, but they are sectioned longitudinally along the direction 20, in order to form sections adjacent longitudinal liner 9a. Each plate is thus cut off longitudinally, for example at the level of each wafer 11. In FIG. 7, one of the plates 14a can be observed which is produced by the succession of adjacent longitudinal sections of plates 14a-b, each having a lower end axially resting on a shoulder 24 located inside the opening 13 of the associated wafer 11.

Finally, it is noted that whatever the embodiment envisaged, the first plates 14a are preferably the only elements of the basket comprising boron or any other neutron absorbing element.

Of course, various modifications can be made by those skilled in the art to the storage devices 1 which have just been described, solely by way of non-limiting examples, and the scope of which is defined by the appended claims.

Claims

1. Storage device (1) for transporting and / or storing nuclear fuel assemblies (2), the storage device being intended to be housed in the cavity (210) of a package (200) for the transport and / or storage of nuclear fuel assemblies, and comprising a number N of adjacent housings (4, 4 '), each intended to receive a nuclear fuel assembly (2), the storage device comprising a plurality transverse structures (11) spaced apart from each other in a longitudinal direction (20) of the storage device, by means of a plurality of spacers (16) arranged between these transverse structures (11), the storage device also comprising liners (9) respectively forming the N adjacent housings (4, 4 '), each liner (9) passing through an opening (13) of at least one of the plurality of transverse structures (11), and of preferably at least several of them, each shirt (9) being produced by successive flats (14a, 14b) in a peripheral direction of the liner, each flat being arranged parallel or substantially parallel to a longitudinal axis of the housing defined internally by the liner (9), characterized in that in at least a transverse plane of the storage device passing through the N shirts (9), at least one of these shirts, and preferably each of at least a plurality of shirts among these N shirts, has an interior housing delimiting surface ( 10) formed in part by:

- an interior surface (14a ') of a first plate (14a) produced with boron; and

- an interior surface (14b ') of a second plate (14b) produced without boron.

2. Storage device according to claim 1, characterized in that in a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N shirts (9), at least 30% of the N shirts each have an interior housing delimiting surface (10) formed in part by:

- an interior surface (14a ') of a first plate (14a) produced with boron; and

- an interior surface (14b ') of a second plate (14b) produced without boron.

3. Storage device according to claim 1 or claim 2, characterized in that the N liners (9) are distributed in liners delimiting peripheral housings (4 ') and liners delimiting interior housings (4), and in that in a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N liners (9), at least 50% of the liners delimiting peripheral housings (4 ') each have an inner delimiting surface housing (10) formed in part by:

- an interior surface (14a ') of a first plate (14a) produced with boron; and

- an interior surface (14b ') of a second plate (14b) produced without boron.

4. Storage device according to any one of the preceding claims, characterized in that in a transverse plane or in each of a plurality of transverse planes of the storage device each passing through the N shirts, at least one of these shirts , and preferably each of a plurality of liners among these N liners, has an interior housing delimiting surface (10) of generally square or rectangular cross section, and formed by:

- an interior surface (14a ') of a first plate (14a) produced with boron;

- an interior surface (14b ') of a second plate (14b) produced without boron; and

- two other plates (14a, 14b), and in that the first plate (14a), the second plate (14b) and the other two plates (14a, 14b) respectively form the four sides of the inner surface of the housing delimitation (10) of generally square or rectangular section.

5. Storage device according to claim 4, characterized in that said two other dishes (14a, 14b) are formed respectively by:

- two first dishes (14a) made with boron; Where

- two second dishes (14b) made without boron; Where

- a first plate (14a) made with boron and a second plate (14b) made without boron.

6. Storage device according to any one of the preceding claims, characterized in that the dishes (14a, 14b) forming the N liners are either first dishes (14a) made with boron, preferably with the same boron content. , or second dishes (14b) produced without boron.

7. Storage device according to any one of the preceding claims, characterized in that at least a first plate (14a) is made in one piece, preferably in an aluminum alloy comprising boron, and / or in that at least a first plate (14a) is provided with a coating comprising boron, preferably applied to an aluminum alloy material.

8. Storage device according to any one of the preceding claims, characterized in that at least one second plate (14b) is made of an aluminum alloy devoid of boron.

9. A storage device according to any one of the preceding claims, characterized in that the shirts (9) each extend over the entire height of the storage device or over substantially all of this height, with each plate (14a, 14b) extending continuously over the entire height of the storage device or over substantially all of this height, or else by being sectioned longitudinally in order to form adjacent longitudinal sections of the liner (9a).

10. Storage device according to claim 9, characterized in that at least one of the longitudinal sections of the jacket (9a) bears axially on one of the transverse structures (11) of the storage device.

11. Storage device according to any one of the preceding claims, characterized in that the transverse structures are wafers (11) each pierced with N openings (13) for receiving the N shirts (9), respectively, the wafers ( 11) preferably being produced without boron.

12. Storage device according to any one of the preceding claims, characterized in that it comprises tie rods (17) for the mechanical retention of the stack of transverse structures (11) and spacers (16) in the longitudinal direction. (20).

13. Storage device according to any one of the preceding claims, characterized in that the number of transverse structures (11), longitudinally spaced from one another, is greater than five, and preferably greater than ten.

14. Packaging (200) for the storage and / or transport of nuclear fuel assemblies, the packaging comprising a cavity (210) in which is housed a storage device (1) according to any one of the preceding claims. .

15. Package (100) comprising a package (200) according to claim 14, as well as nuclear fuel assemblies (2) arranged in the adjacent housings (4, 4 ') of the storage device (1) of this package (200 ).