EP3572762A1 - Mobile device for storing explosive - Google Patents

Abstract

An explosive storage device 2 comprises a box 4 and a drawer 6 slidably mounted relative to each other in a main direction X, each of substantially parallelepipedal shape, and each comprising five closed faces and one open face 8 14. The open face 8 of the box 4 is orthogonal to said main direction X and the open faces 8, 14 of the slide 6 and the box 4 are orthogonal. The drawer 6 is able to contain an object. The casing 4 and the drawer 6 are lockable relative to each other. The casing 4 and the drawer 6 each comprise a dissipator assembly comprising a plurality of profiled tubes, where the closed faces of the drawer 6 and the box 4 are each covered by their respective dissipating assemblies, the dissipator assembly of the box 4 is fixed to the interior of said box 4, and the profiled tubes are stacked.

Description

The invention relates to an explosive storage device.

The storage and transport of explosive objects involves drastic safety rules. Indeed, given the explosive nature of objects, it is essential to prevent an accidental explosion causing damage to people or the nearby environment. There is a need for robust containers that can absorb the mechanical and thermal energy of an accidental internal explosion and limit damage to the outside of the box. However, such containers would require thick walls in a resilient material, for example armor steels or alloys, which would make them particularly heavy and expensive.

The present invention improves the situation.

The invention proposes an explosive storage device, comprising a box and a drawer slidably mounted relative to one another in a main direction, each of substantially parallelepipedal shape, and each comprising five closed faces and one open face. , the open face of the box being orthogonal to said main direction and the open faces of the drawer and the box being orthogonal, the drawer being further adapted to contain at least one object. The box and the drawer each comprise a dissipator assembly comprising a plurality of tubes or profiled bars. The closed faces of the drawer and the box are each covered by their respective dissipating assemblies. The heatsink assembly of the box is fixed inside said box. The tubes or profile bars are stacked. The profiled tubes or bars can diffuse an internal overpressure.

Such a device is manually transportable.

In one embodiment, the drawer of the explosive storage device comprises one or more cells opening on the open face of the drawer, insulated from the closed faces of the drawer and isolated from each other at least by the dissipator assembly of the drawer.

In one embodiment, the box and the drawer each comprise an outer envelope and the box comprises an inner envelope. The heatsink assembly of the box is disposed between the two envelopes of the box. The heatsink assembly of the drawer is disposed within the outer casing of the drawer.

In one embodiment, at least one of the closed sides of the casing of the casing, on a different side of the side of the open face of the drawer, is perforated.

In one embodiment, at least one of the closed sides of the drawer covers on a different side of the side of the open side of the box is perforated.

In one embodiment, the rate of perforation of each envelope is less than the rate of perforation of the envelopes that said envelope encompasses.

In one embodiment, the profiled tubes of the dissipator assembly are cubic in shape.

In one embodiment, the profiled tubes of the dissipator assembly are of identical dimensions.

In one embodiment, the profiled tubes of the dissipator assembly are disposed in their respective dissipator assembly in a compact stack of cubes.

In one embodiment, the axes of the profiled tubes of the dissipator assembly are oriented in different directions in a substantially random manner.

In one embodiment, the compact stack of the dissipator assembly of the box comprises one to four layers of profiled tubes between the two casings of the box.

In one embodiment, the profiled tubes are made of resilient material, in particular shielded steel, alloy, ceramic or ballistic composite or composite based on aramid fibers, or a multilayer thereof.

In one embodiment, the sliding connection between the drawer and the box comprises sliding rails.

In one embodiment, a reinforcing belt is disposed around at least one dissipator assembly.

In one embodiment the reinforcing belt comprises one or more layers of aramid, optionally crossed with each other.

In one embodiment, the box comprises a damper disposed on the closed face of the box on the side of the open face of the drawer.

In one embodiment, the damper includes at least one deformable element capable of absorbing mechanical energy, in particular an element selected from the group comprising one or more plastic layers, a foam, or a spiral steel sheath assembly. plastic or a combination of elements of said group.

In one embodiment, at least two opposite closed faces of the outer casing of the box are of complementary shapes to allow the stacking of several boxes.

In one embodiment, the box includes a drawer latch to prevent the drawer from sliding out of the box.

In one embodiment, the drawer latch is capable of absorbing mechanical energy in the event of an explosion, if any.

In one embodiment, the explosive storage device is movable and transportable manually.

• la figure 1 est une vue en perspective du dispositif de stockage d'explosif en position ouverte ;
• la figure 2 est une vue en perspective avant du dessus du tiroir du dispositif de stockage d'explosif en position ouverte ;
• la figure 3 est une vue en perspective avant du dispositif de stockage d'explosif en position fermée, avec rabat relevé ;
• la figure 4 est une vue en perspective avant du dispositif de stockage d'explosif, en position fermée, avec rabat abaissé ;
• la figure 5 est une vue en perspective arrière du caisson du dispositif de stockage d'explosif;
• la figure 6 est une vue de dessus d'un dispositif de stockage d'explosif mono-alvéole ;
• la figure 7 est une vue schématique en perspective du dispositif de stockage d'explosif ;
• la figure 8 est une vue schématique en perspective du dispositif de stockage d'explosif selon un autre mode de réalisation de l'invention ;
• la figure 9 est une vue en coupe du caisson selon IX-IX de la figure 7 ;
• la figure 10 est une vue de dessus schématique d'un assemblage dissipateur avec des tubes profilés de section circulaire en empilement compact ;
• la figure 11 est une vue schématique de dessus d'un assemblage dissipateur selon un empilement non compact ;
• la figure 12 est une vue schématique de dessus de l'intérieur du tiroir du dispositif de stockage d'explosif ; et
• la figure 13 est une vue en coupe selon IX-IX d'une portion d'un assemblage dissipateur selon un mode de réalisation à orientation aléatoire.

Other characteristics and advantages of the invention will become apparent on reading the following detailed description, relating to examples given for illustrative and non-limiting purposes, as well as to the examination of the appended drawings, in which:

• the figure 1 is a perspective view of the explosive storage device in the open position;
• the figure 2 is a front perspective view of the top of the drawer of the explosive storage device in the open position;
• the figure 3 is a front perspective view of the explosive storage device in the closed position, with raised flap;
• the figure 4 is a front perspective view of the explosive storage device, in the closed position, with the flap down;
• the figure 5 is a rear perspective view of the box of the explosive storage device;
• the figure 6 is a top view of a mono-cell explosive storage device;
• the figure 7 is a schematic perspective view of the explosive storage device;
• the figure 8 is a schematic perspective view of the explosive storage device according to another embodiment of the invention;
• the figure 9 is a sectional view of the box according to IX-IX of the figure 7 ;
• the figure 10 is a schematic top view of a dissipator assembly with profile tubes of circular section in compact stack;
• the figure 11 is a schematic view from above of a dissipator assembly according to a non-compact stack;
• the figure 12 is a schematic top view of the interior of the drawer of the explosive storage device; and
• the figure 13 is a sectional view along IX-IX of a portion of a dissipator assembly according to a random orientation embodiment.

The attached drawings contain, for the most part, elements of a certain character. They can therefore not only serve to better understand the present description, but also contribute to the definition of the invention, if any.

The explosive storage device 2, cf. figure 1 , comprises a box 4 and a drawer 6. The box 4 is substantially of parallelepipedal shape. The drawer 6 is substantially of parallelepiped shape. The box 4 and the drawer 6 are slidably mounted relative to each other in a main direction X. Directions Y and Z are defined in an orthogonal reference with X. The drawer 6 is able to contain at least one object. The sliding is done between an open position, where the drawer 6 is at least partially out of the box 4, and a closed position, where the drawer 6 is substantially inside the box 4. The box 4 comprises a front face 8, two side faces 19, an upper face 20, a lower face, and a rear face. When the drawer 6 leaves the box 4, it passes through the open front face 8 of the box 4. The rear face, the upper face, the lower face and the side faces of the box 4 are closed and, here, full.

A guide rail 10 may be disposed inside the box on the lateral faces of the box 4. The guide rail 10 can support the sliding between the box 4 and the drawer 6.

The drawer 6 comprises an upper face, a front face, two lateral faces, a lower face, and a rear face. The upper face of the drawer 6 is an open face 14. The front face of the drawer 6, the rear face of the drawer 6, the lower face of the drawer 6 and the lateral faces of the drawer 6 are closed and, here, solid. The drawer 6 comprises several cells 12 opening on the open face 14 of the drawer. The cells 12 are accessible when the drawer 6 is in the open position.

A flap 16 may be mounted on the upper face of the casing 4. The flap 16 may cover the open face 8 of the casing 4 when the drawer is in the closed position. The flap 16 may be flexible, or rigid and articulated flap.

The casing 4 is here provided with transport handles 18, located on the two opposite lateral faces of the casing 4.

The side faces, the upper face, the lower face, the front face and the rear face of the drawer define the outer casing 24 of the drawer.

The faces of the box 4 and the drawer 6 may comprise sheets of metal sheet.

In another embodiment, the box and the drawer can slide directly against each other.

The drawer 6 comprises a drawer latch 110 to prevent the drawer 6 from sliding out of the box 4. The drawer latch 110 may comprise a rib 112. The rib 112 projects with the drawer 6. The rib 112 is arranged on the face 22 before the drawer 6. The rib 112 may be integral with the drawer 6 or fixed to the drawer 6. The rib 112 is substantially elongate shape in a horizontal direction. One or more holes 114 may be formed in the rib 112. The lock further comprises a locking member, cf. Figures 3 and 4 fixed to the casing 4 passing through the holes 114 when the device is in the closed and locked position.

The cells 12 may be spaced regularly. The cells 12 are at a distance from each other. The cells 12 are isolated from each other. Each cell 12 may contain at least one explosive object. Thus, if the contents of a cell 12 were to explode, the propagation of the explosion to the other cells 12 would be limited. The bottom of the cells 12 is at a distance from the lower face of the drawer 6.

The cells 12 each comprise a cell wall 26. The cell wall 26 may be made with a pipe, for example a corrugated PVC cut pipe (cf. figure 2 ). The cell wall 26 may be more generally plastic. The cells 12 may be encircled by one or more aramid fiber belts, in order to improve their behavior, see figure 12 .

The figure 3 is a front view of the explosive storage device in the closed position.

The drawer 6 and the box 4 are here in the closed position. The open face 8 of the box 4 may be hidden by the flap 16, which is here raised.

The drawer latch 110 comprises a locking member 116.

The locking member 116 may be formed of a U-shaped steel bar, with two branches 118 and 120 and a base 122, cf. figure 4 . The two branches 118 and 120 can pass through a hole 114 of the rib 112. The free ends of the two branches 118 and 120 of the locking member 116 can each be inserted in a hole 122 formed in the front edge of the lower face 28 of the box 4.

The casing 4 and the drawer 6 are in the closed position. The flap 16 covers the open face 8 of the box. The upper face 20 of the box 4 supports the base 120 of the locking member 116. The locking member 116 can rest on the upper face 20 of the box 4.

Alternatively, the drawer latch 110 may include a locking member comprising a straight bar instead of a U-bar.

The drawer latch 110 blocks the drawer 6 inside the box 4, and thus prevents accidental opening of the drawer 4. The drawer latch 110 can also be designed to collect a portion of the mechanical energy in the event of an explosion The blocking member 116 can then be made of steel, in particular shielded steel.

The upper closed face 200 of the box 4 may comprise a damper 250. The damper 250 is placed on the side of the open face 14 of the drawer 6. The damper 250 is adapted to absorb a portion of the energy released during a explosion of the contents of the drawer 6. Indeed, the cells 12 open on the open face 14 of the drawer 6. Also the damper 250 reinforces the upper closed surface 200 of the box.

The damper 250 may comprise a material capable of absorbing and then dissipating mechanical energy, in particular a foam, a plastics material, one or more springs, or a steel sheath spiral assembly or a combination of elements of said group, in particular a multilayer of materials, at least one resilient and at least one deformable.

The plastic steel sheath spiral assembly comprises a hose of elastic or plastic material arranged in a spiral. A steel coil is arranged around or inside the pipe. The steel coil can be arranged helically. The steel coil can be a rod.

The rear face 255 of the box 4 can be assembled with the side faces 19 and the upper face 20 by screws 260 or by welding.

In one embodiment, the explosive storage device 2 may comprise a single cell 12. The cell 12 is isolated from the closed walls 22 of the spool 4 by a dissipator assembly 400 able to dissipate mechanical energy, in particular caused by an explosion. The cell 12 is isolated from the lower face of the drawer 6 by the dissipator assembly 400.

The box 4 comprises five closed faces 200 and an open face 8, through which the slide 6 can slide in the box 4. The slide 6 comprises an open face 14 and five closed faces 220.

The open face 8 of the box and the open face 14 of the drawer are orthogonal. The explosive storage device 2 is then in a matchbox configuration with a single opening.

The casing 4 comprises an outer casing 210 and an inner casing 212. The outer casing 210 of the casing delimits the casing 4 and the inner casing 212 delimits the inside of the casing 4. The drawer 6 is delimited by its outer casing 24.

This configuration offers to open the drawer with cells upwards, which prevents a user from dropping the contents of a cell at the opening.

The open face 8 of the box 4 is on a different side of the side of the open face 14 of the drawer 6. In fact, the open face 8 is therefore either orthogonal to the open face 14, see figure 8 , opposite, see figure 9 . Indeed, as the cells 12 open on the open face 14, in case of explosion of the contents of a cell 12, the mechanical energy passes largely through the open face 14 of the drawer 6. The upper face 20 of the drawer 4 and the dissipator device 300 absorb a large part of the explosion, if any. In order to increase the resistance of the device in the event of an explosion, the open face 14 of the slide 6 can therefore be on the side of one of the closed faces 20 of the box 4. In one embodiment, the open face 8 of the box and the open face 14 of the slide are opposite to each other in the main direction X. The two open faces 8 and 14 are not on the same side.

The casing 4 comprises an outer casing 210 and an inner casing 212. The casings 210 and 212 have a small thickness relative to the thickness of the wall of the casing 4. Between the casings 210 and 212 is disposed a dissipator assembly 300. dissipator assembly 300 comprises a plurality of profiled tubes 302 of constant section.

Each profiled tube 302 has an axis 304. In the figure 9 the axes 304 are oriented orthogonally to the YZ cutting plane, ie in the X direction. The axes 304 may be parallel to one another. To maintain good readability, only two axes 304 are represented on the figure 9 , but each profiled tube 302 has an axis 304.

In another embodiment, the pins 304 may be directed in the Y direction. In another embodiment, the pins 304 may be in the Z direction.

The profiled tubes 302 may be identical in shape, and / or identical in size. They can be glued or welded together. They can also hold each other by the only mechanical constraint of the envelopes 210 and 212.

In one embodiment, these profiled tubes 302 are of rectangular section, and in particular here of square section.

The profiled tubes 302 may be arranged in a compact stack, that is to say a stack minimizing the occupied space. For example, in the embodiments comprising profiled tubes 302 with a square section, the compact stack may be a regular stack according to a square mesh geometric network 306. The square mesh 306 is represented here by way of illustration. The dissipator assembly 300 may comprise three layers of profiled tubes 30, cf. figure 9 . In other implementations, the dissipator assembly 300 may comprise one to ten layers, preferably one to four layers. Finally, in another embodiment, the dissipator assembly 300 may comprise a single layer of profiled tubes 302.

The shells 210 and 212 may have a thickness of 0.2 to 3 mm. The cubic shaped profile tubes may have a side of about 0.2 to 10 mm, especially 3 to 10 mm. The envelopes 210 and 212 may be made of sheet steel.

The cubes are made of resilient material, for example a steel.

The profiled tubes 302 may be spaced from each other to allow overpressure to be diffused, if necessary. In fact, in the event of an explosion, the generated overpressure will circulate in the profiled tubes 302, and enter each available gap between two profiled tubes 302 (possibly deforming them if the pressure is sufficient). By hydrodynamic effects, the overpressure leads in part into the cavities of the profiled tubes 302. This will have the effect of dissipating the energy of the explosion within the dissipator assembly 300.

Thus, the dissipator assembly 300 has an absorption capacity greater than a wall of resilient material of a thickness equal to the thickness of the outer casings 210 and inner 212 of the casing 4. In addition, a much greater mass would have to be provided for achieve with solid walls of resilient material (eg shielded steel) an absorption capacity equivalent to that of a dissipator assembly. The invention thus makes it possible to obtain, for a reduced cost and a minimal mass, a large capacity for absorbing internal explosions.

In order to improve the energy evacuation of the explosive storage device, the outer casing 210 and the inner casing 212 of the casing 4 may comprise perforations 320 and 322 on at least one of the closed faces 200 of each casing 210 and 212. Punctures 420 may be provided on the outer casing 24 of the drawer 6.

The perforation rate of the envelopes may decrease with distance to the center of the device. In other words, the perforation rate of a given envelope is less than the perforation rate of the envelopes that the given envelope includes. The perforation rate of a given envelope is greater than the perforation rate of the envelopes that encompass the given envelope. The underside of the drawer 6 being potentially close to the bottom of the cells 12, the lower face of the slide 6 may have a zero perforation rate.

The rate of perforation of a closed face can vary between 10% and 90% of the total surface of said face, preferably between 20% and 60% of the total surface of said closed and perforated face.

Thus, the dissipator assembly 300 of the box 4 is fixed inside said box 4, and is encompassed by the outer shell 210 of the box 4.

The compact stack of tubes of the same radius is a stack according to an equilateral triangular mesh geometric network 308. The equilateral triangular mesh 308 is indicated here by way of illustration. The dissipator assembly 300 may comprise one to four layers of profiled tubes 302 of circular section, here four layers. The axes 304 of the profiled tubes 302 are parallel to each other. The axes 304 may be orthogonal or parallel to the envelopes 210 and 212.

In one embodiment, the profiled tubes 302 are of circular section. The profiled tubes are stacked according to a square mesh network 310 less compact than the triangular mesh network when the section of the profiled tubes 302 is circular.

The cells 12 each comprise a cell wall 26. The wall 26 is here cylindrical but can be of any shape (tubular with square section, polygonal section, semi-spherical, polyhedral, etc.). The wall 26 opens on the open face 14 of the drawer 6. The drawer 6 also comprises an outer casing 24.

The drawer 6 comprises a dissipator assembly 400. The dissipator assembly 400 comprises a structure similar to that of the dissipator assembly 300 of the casing 4. Also, the characteristics and implementations described for the dissipator assembly 300 of the casing 4 are valid for the dissipator assembly 400 of the drawer 6.

However, the two dissipator assemblies 300 and 400 differ in that the dissipator assembly 300 can be between the two outer casings 210 and inner 212 of the casing 4, while the dissipator assembly 400 is included in the outer casing 24 of the drawer 6 and includes the at least one cell 12.

The cells 12 are isolated from each other. The cells are isolated from the closed walls 220 of the spool 6 by the dissipator assembly 400. Thus, thanks to the absorption properties of the dissipator assembly 400, if the contents of a given cell 12 come to explode, the dissipator assembly 400 allows to confine the explosion to the cell 12 given only, and thus prevent the propagation of the explosion to other cells 12, thus protecting their contents.

A reinforcing belt 450 may be arranged, for example, wound around one or more cells 12. The reinforcing belt 450 may comprise an aramid layer or several layers of aramid crossed with each other. In particular, two crossed aramid belts can be used. The reinforcement belt 450 advantageously makes it possible to improve the strength and the cohesion of the dissipator assembly 400. The reinforcement belt 450 advantageously makes it possible to improve the strength and the cohesion of the cells 12.

In one embodiment, the orientation of the axes of the tubes or profiled bars is random. The dissipator assembly 500, see figure 13 can be implemented in place of the dissipator assembly 300 of the casing 4. The dissipator assembly 500 can be implemented in place of the dissipator assembly 400 of the drawer 6.

• les tubes profilés 502 ont un axe orienté dans la direction X,
• les tubes profilés 504 ont un axe orienté dans la direction Y et
• les tubes profilés 506 ont un axe orienté dans la direction Z.

The dissipator assembly 500 comprises a plurality of profiled tubes 502, 504 and 506. These profiled tubes may be of cubic shape, that is to say of square section and of identical length, width and thickness. The difference from the previous embodiments (where the profiled tubes have parallel axes within the same dissipator assembly 300) is that here:

• the profiled tubes 502 have an axis oriented in the X direction,
• the profiled tubes 504 have an axis oriented in the Y direction and
• the profiled tubes 506 have an axis oriented in the Z direction.

The orientations of the profiled tubes 502, 504 and 506 may be such that the dissipator assembly 500 thus made has no preferred direction. In other words, orientations are substantially random, without a fixed pattern. The random configuration advantageously makes it possible to diffuse the energy of an explosion, if necessary, into the entire structure of the dissipator assembly 500, in an isotropic manner.

In another variant of dissipating assembly 500 with random orientation, the profiled tubes 502 can be circular, or in regular polygons, for example in hexagon. Their length, width and thickness are then also identical in order to be able to stack the profiled tubes 502, 504 and 506 despite the heterogeneity of the orientation of their axes.

The profiled tubes 502 may be made of a resilient material. In particular, the profiled tubes 502 may be made of shielded steel, alloy, ceramic or ballistic composite or aramid based, or a multilayer combination thereof.

A reinforcing belt 550 may be disposed, for example, wound around the dissipator assembly 500. The reinforcing belt 550 may comprise an aramid layer or a plurality of aramid layers crossed with each other. In particular, two crossed aramid layers can be used. The reinforcing belt advantageously makes it possible to improve the strength and the cohesion of the dissipator assembly 500.

Two opposite closed faces of the box 4, in particular its side faces or its upper and lower faces may be of complementary shapes to allow the stacking of several boxes. This advantageously provides a key differentiating the top and bottom of the explosive storage device, which is useful in view of the explosive nature of the contents of the drawer.

In one embodiment, the profiled tubes 302, 402 and / or 502 may be profiled bars. Alternatively, the dissipator assemblies 300 and / or 400 may comprise profiled bars and profiled tubes. The distribution of profiled tubes and profiled bars can be uniform, regular in a pattern, or random.

Claims (13)

An explosive storage device (2), comprising a box (4) and a slide (6) slidably mounted relative to each other in a main direction X, each of substantially parallelepipedic shape, and each comprising five faces closed (200, 220) and an open face (8, 14), the open face (8) of the box (4) being orthogonal to said main direction X and the open faces (8, 14) of the drawer (6) and the box (4) being orthogonal, the drawer (6) being further adapted to contain at least one object, the box (4) and the drawer (6) being lockable relative to each other, wherein the box (4) and the spool (6) each comprise a dissipator assembly (300, 400, 500) comprising a plurality of shaped tubes or bars (302, 402, 502), wherein: the closed faces (200, 220) of the slide (6) and of the box (4) are each covered by their respective dissipating assemblies (300, 400, 500), the dissipator assembly (300, 500) of the box (4) is fixed inside said box (4), the profiled tubes or bars (302, 402, 502) are stacked. An explosive storage device (2) according to claim 1, wherein the slide (6) comprises one or more cells (12) opening on the open face (14) of the slide (6), and being isolated from the closed faces ( 220) of the spool (4) and isolated from each other by the dissipator assembly (400, 500) of the spool (4). An explosive storage device (2) according to one of the preceding claims, wherein the box (4) and the drawer (6) each comprise an outer shell (210, 24) and the box comprising an inner shell (212) , the dissipator assembly (300, 500) of the box (4) being disposed between the two casings (210, 212) of the casing (4), and the dissipator assembly (400, 500) of the drawer (6) being arranged at inside the outer casing (24) of the drawer (4). An explosive storage device (2) according to claim 3, wherein at least one of the closed faces (200, 220) of the casings (24, 210, 212) of the casing (4) and the drawer (6) which is not on the side of an open face (8, 14) is perforated, the perforation rate of each envelope (24, 210, 212) being less than the perforation rate of the envelopes (24, 210, 212) that said envelope (24, 210, 212) encompasses. An explosive storage device according to one of the preceding claims, wherein the profiled tubes or bars are of cubic shape, of identical dimensions, and arranged in their respective dissipator assembly in a compact stack of cubes, and in which their axes are oriented in different directions in a substantially random manner. Explosive storage device (2) according to the preceding claim, in which the compact stack of the dissipator assembly (300, 500) of the box (4) comprises one to four layers of profiled tubes or bars (302, 402, 502) between the two shells (210, 212) of the box (4). An explosive storage device (2) according to one of the preceding claims, wherein the profiled tubes or bars (302, 402, 502) are made of a resilient material, in particular shielded steel, alloy, ceramic or ballistic composite. or based on aramid fibers, or a multilayer combination thereof. Explosive storage device (2) according to one of the preceding claims, wherein the sliding connection between the drawer (4) and the box (6) comprises sliding rails (10). An explosive storage device (2) according to one of the preceding claims, wherein a reinforcing belt (450, 550) is disposed around each dissipator assembly (300, 400, 500), said reinforcing belt (450, 550) comprising an aramid layer or several layers of aramid crossed with each other. An explosive storage device (2) according to one of the preceding claims, wherein the box (4) comprises a damper (250) disposed on the closed face (20) of the box (4) on the side of the open face ( 14) of the spool (6) including at least one deformable element capable of absorbing mechanical energy, in particular an element selected from the group comprising one or more layers of plastic material, a foam, or a spiral assembly steel sheath plastic or a combination of elements of said group. An explosive storage device (2) according to one of claims 2 to 10, wherein at least two opposite closed faces (19, 20, 200) of the envelope outside (210) of the box (4) are of complementary shapes to allow the stacking of several boxes (4). An explosive storage device (2) according to one of the preceding claims, wherein the box (4) comprises a drawer latch (110) for preventing the drawer (6) from sliding out of the box (4) and absorbing mechanical energy in case of explosion, if any. An explosive storage device according to one of the preceding claims, wherein the explosive storage device (2) is movable and transportable manually.

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