ES2352881T3 - SECURITY DEVICE FOR EXPLOSIVE CONTAINERS, EXPLOSIVE CONTAINERS AND METHOD FOR PREPARING SAFE CONTAINERS FOR EXPLOSIVES. - Google Patents

Abstract

A safety device (4) for explosive containers (8), and in particular for insensitive explosives, suitable for ensuring quick and effective venting of the gases produced in the containment chamber (12) of the explosive, if the environment surrounding the explosive container is subject to strong overheating. The device (4) prevents the danger of explosions and ensures duration and reliability over time, even during all the steps of transport and storage of the explosive containers (8).

Description

Safety device for containers explosives, explosives containers and method of preparation safe containers for explosives.

The present invention relates to a safety device for explosives containers, a related explosives container and a method to prepare safe explosive containers; In particular, this invention is preferably applied in the field of explosives of insensitive ammunition type IM (insensitive ammunition).

The insensitive explosives are characterized because they do not explode suddenly when they are directly reached by a flame or, in any case, when subjected to a high and / or sudden increase in temperature. These explosives, like all explosives have a conditioning temperature for on top of which they decompose, releasing quantities of gases: these gases can be easily expelled from the chamber of explosive containment to prevent high overpressures cause the breakage of the enclosure and also the decomposition and consequent explosion / detonation. The endurance and time of reaction depend on the type of explosive used.

In the field of insensitive explosives, know, therefore, use safe devices suitable for favor the extraction of the gases generated before it reach the critical conditioning temperature, avoiding strong reactions or, in any case, limiting the resistance of the reaction as much as possible.

Known devices, for example, provide the use of covers or sealing rings made of a material that has a melting point calibrated to allow the lid, in the vicinity of the critical temperatures for the explosive, it holster and release suitable purge openings to allow gas extraction in order to prevent the pressure in the chamber of containment of the explosive reach limit values. These devices are known from the documents US-A-5155298, US-2003/205161 A1 and US H1144H.

The prior art devices do not ensure optimal performance in storage conditions and / or transport of the explosives container in conditions of high overheating

In fact, during storage or transport, explosive containers often undergo continuous mechanical stresses, such as shocks or vibrations, which they could break the covers dangerously. In fact, you are covers have considerable weights and are made of alloys metallic that, at room temperature, are quite fragile.

In addition, in the case of merger of covers after heavy overheating, often prior art covers do not ensure adequate opening of gas purges, but have metal parts that are adhere to the purges, without ensuring adequate extraction of gases

Starting from document US 2003/205161 A1, the problem that the present invention intends to solve is to prepare a safety device that resolves the aforementioned disadvantages with reference to the prior art and, in particular, a device that ensures quick and efficient removal to continuation of prolonged exposure of the container to a elevated overheating of the surrounding environment and at the same weather, good mechanical resistance in all conditions of storage and / or transport of the explosives container.

These disadvantages are resolved by safety device according to claim 1.

Other embodiments of the security device according to the invention are described in the claims later.

Other features and advantages of this invention will be more clearly appreciated from the following description of a non-limiting embodiment, in which:

Figure 1 shows a sectional view of a explosive container comprising a safety device according to an embodiment of the present invention;

Figure 2 shows a sectional view of a explosives container comprising a device according to a additional feature of the present invention;

Figure 3 shows a sectional view of a further embodiment of the security device of the present invention.

With reference to the previous figures, the numerical reference 4 generally refers to a device of Safety for 8 containers of explosive substances.

8 containers of explosive substances they comprise, for example, a chamber 12 for receiving the substance explosive, preferably sealed hydraulically or pneumatically, bounded by at least one closing wall 16. The 16 wall of closure has a purge opening 20 suitable to house the less partially the device 4. Preferably, the opening 20 of purge has a circular shape or, in any case, axially symmetric in relation to an axis of symmetry X-X.

Advantageously, the device 4 comprises the minus a closing structure 28 suitable for closing hermetically the purge opening 20.

Preferably, the closing structure 28 is contrary to the purge opening 20; by For example, the closing structure 28 is in the form of a disk.

The device 4 comprises means 34 of retention of the closing structure 28, mechanically separated from the closing structure 28 and suitable for strengthening the structure 28 closing in the purge opening 20.

According to one embodiment, means 34 of retention comprise a fusion element 38, suitable for melt and release the closure structure 28 in the case of a overheating of the environment surrounding the material container explosive; the fusion element 38 in an assembled configuration at least partially interferes with the closure structure 28 for prevent the removal of the closing structure 28 of the chamber 12 of containment.

Preferably, the fusion element 38 has an annular shape, so that in an assembled configuration it is axially symmetric with respect to the X-X axis of the opening 20.

Advantageously, the retaining means 38 comprise a splice element 42 which, in an assembled configuration interferes with the fusion element 38 in order to block the fusion element 38 in position against the structure 28 of
closing.

Therefore, the fusion element 38, in a assembled configuration, is previously introduced in compression between the connecting element 42 and the closing structure 28, according to an axial direction parallel to said X-X axis of the opening 20.

According to a possible embodiment, element 42 of splice comprises a first plate 48 suitable for exercising influence on the compression of a part of the element 38 of fusion in contact with the closure structure 28.

Preferably, the first plate 48 is shaped substantially contrary to the closing structure 28, in order to have smaller global external dimensions or equal to the overall dimensions of structure 28 of closing.

According to one embodiment, the first plate 48 and the closure structure 28 are in the form of discs that have substantially the same diameter.

Preferably, the splice element 42 is mechanically secured to the closing structure 28 by means of consolidation such as connections that can be removed from threaded type 52. According to a further embodiment (figure 3) the splice element 42 is not mechanically anchored to the closing structure 28 but to the closing wall 16. The wall 28 of closure is directly located in a first accommodation 53 obtained in the thickness of the wall 16 and delimited by an edge 54 of stop axially tightening the closing structure against the wall 16.

According to a possible embodiment, the means of securing comprise spacer bearings 56 arranged between the first plate 48 and the closing structure 28. Bearings 56 are preferably inserted coaxially with respect to the connections threaded 52 and have the function of avoiding deformations by folding of the closing structure or of the first plate.

According to a possible embodiment, a purge valve 60 between first plate 48 and structure 28 of closure, suitable for intercepting gases from chamber 12 of containment and expel them out of said chamber 12, as soon as exceed a limit pressure value.

According to one embodiment, splice element 42 comprises a second plate 64 suitable for exerting an influence compression on a portion of the contact melting element 38 with a portion of said closing wall 16 or with a flange 80 of device support 4, as described better with later. The first and second plates 48, 64 are mechanically separated from each other.

Preferably, the first plate is in the form of disk, with an opposite shape in relation to structure 28 of closure and the second plate 64 has the shape of a circular crown, which has an internal diameter greater than the external diameter of the first plate 48 and of the closing structure 28.

According to a variation of embodiment (figure 2), the fusion element 38 comprises at least one guide rib 68 suitable to facilitate coupling between element 38 itself and at least one between the closing structure 28 and the first plate 48. In other words, the edge forms a containment guide for the closure structure 28 and the first plate 48.

According to one embodiment, the fusion element 38 it comprises a bismuth-tin alloy, which has a melting point between 135 ° C and 145 ° C.

Preferably, the fusion element is made of a tin alloy eutectic bismuth that has a melting point equal to 138 ° C.

According to a variant embodiment, the element 38 fusion comprises high molecular density polyethylene (HDPE) which has a melting point equal to about 135 ° C.

Preferably, the fusion element 38 is a ring that has a dimensional relationship between a radial thickness and an axial thickness greater than or equal to 1 and, more particularly said Dimensional ratio is between 2 and 2.5. By thickness axial is to indicate a thickness measured along one direction parallel to the X-X axis of the purge opening 20. By radial thickness you want to indicate a thickness measured along of a radial direction perpendicular to the X-X axis e incident with it.

The closing structure 28 is made preferably of aluminum in order to allow a good resistance to internal chamber pressures and at the same time limit the weight of the component itself; mass containment is useful to limit tensions after shocks and / or vibrations that the closing structure 28 would transmit to the means 34, 38, 42 retention.

Advantageously the device 4 comprises means 74 suitable sealing to ensure the hydraulic closure of the containment chamber 12. For example, said sealing means 74 they comprise at least one o-ring 76 disposed between the wall 16 closing and closing structure 28 (figure 3).

According to a further example, means 74 of sealed comprise at least one o-ring 76 disposed between the closure structure 28 and the fusion element 38 (Figure 1).

According to a further possible embodiment, the device 4 comprises a flange 80 suitable for insertion into the purge opening 20 and to at least partially accommodate the closing structure 28, in order to hermetically close, together with the closing structure 28, the purge opening 20 (figures
1-2).

For example, flange 80 may comprise a fixing clamp 84 suitable for splicing with wall 16 of closure at the insertion of the flange 80 in the opening 20 and for allow fixing the flange 80 to said closing wall 16, by example, via threaded connections 52.

Preferably, a sealing ring, such as a O-ring 76, is inserted between clamp 84 and the wall 16 closing.

The flange 80 delimits a second housing 86 to accommodate said fusion element 38. It is possible to provide a second coaxial flange 90 relative to flange 80, for example, to adapt the dimensions of the device to those of the opening 20 of purge.

The operation of a safety device according to the present invention will now be described.
tion.

In operating or transport conditions or normal storage, device and container relative explosives are normally exposed to a temperature between -40ºC and + 70ºC.

In the presence of any shocks or vibrations, the function ring is in a state of tension pre-compression so that any tensile stress, for example, due to folding stresses, it is canceled or in any case it is buffered or reduced by said state tensile.

Any gases released inside the containment chamber 12 cannot leave it, since the chamber 12 is completely sealed. Deformations by folding induced by these gases are supported by the structure 28 closing and by means 34, 38, 42 of retention and any tensile tensile states are canceled, at least partially, by said tension compression state.

In addition to this, as the melting ring has a "chubby" structure geometry, this component is essentially deforms by shear actions instead of by folding actions. This geometry increases the resistance component mechanics up to even impulsive deformations combined with gas pressure actions inside the camera.

If the external temperature reaches the point of fusion of the fusion element 38, normally equal to at about 138 ° C, said melting element 38 melts.

Following the merger, means 34, 38, 42 retention are no longer able to block the structure 28 of closure, as the fusion disk melts and the structure of closure, also thanks to its weight, tends to fall and leave the relative housing, releasing the purge opening 20 for the gases contained in chamber 12; optionally, the push action of the gases themselves can favor the expulsion of the structure 28 closing.

In addition, the first plate 48 represents a mass in solidarity with the closing structure 28, placed externally in relation to opening 20 and chamber 12 containment, bringing the global barycenter of structure 28 of closure and the first plate system 48 is external to the chamber 12 of containment and favors the gravity fall of structure 28 of closing.

The exit of the closing structure 28 of its accommodation does not exhibit adhesion risks that could block it at its opening 20, at least partially closing the section of gas outlet: in fact, after the melting of the ring, the step section available for the closing structure increases, since that the closing structure finds a passage section of the second plate 64 or a flange 80 that are larger than the dimensions of the closing structure 28 and the first plate 48.

In addition, the closing structure is normally arranged with a slight clearance in relation to the relevant opening, since the lock in its own position structure takes place through means 34, 38, 42 of retention and airtight sealing of gases is obtained by means Special seal.

The method for prepare safe explosive containers according to this invention.

In particular, security devices according to the present invention can be advantageously applied also to existing explosives containers without devices security and provided with few security devices effective.

The method is to determine an opening of purge existing in a wall 16 of the containment chamber 12 of the explosives container As an alternative, said opening 20 of purge is made in a wall 16 of closing chamber 12 of containment of explosive material.

Then a tightly inserted safety device 4 according to the present invention in said purge opening 20.

Advantageously, the device can be inserted in a previously assembled configuration, that is, having already mechanically connected to each other the fusion element 38, the closure structure 28, splice element 42 and any flanges 80, 90.

As can be understood from the description, the safety device according to the present invention allows to overcome the disadvantages of the safety devices of prior art

The device has a small mass in comparison with prior art fusion discs; this form, the inertia forces that result from shocks are avoided and / or variations, which could cause damage or cracks in the own disk.

The device is advantageously arranged in a state of tension pre-compression between respective flange retention means and counter-flange; in this way, it is possible to avoid that, following the dynamic action of shocks and / or vibrations, the fusion element can undergo stresses of traction that could generate cracking. Thus, the device is resistant to environmental stresses that you can experience the container to which it is applied during the stages of existence, logistics or operation, that is, it is resistant to shocks and vibrations, as well as high ambient temperatures

Advantageously, the device allows the maintenance of the hydraulic and pneumatic seal of the chamber containment of explosives in order to protect the explosive from possible risks of contamination of other substances, in ordinary logistic and operating conditions. Said of another mode, the device ensures airtight closure until activation for extraordinary overheating conditions.

In addition to this, the security device according to the invention ensures fast and efficient gas extraction before the operating limit temperature of the explosive. In fact, following the fusion of the ring, the closure structure can be easily ejected without any risk of adhesions; in particular, the expulsion of the structure closing can take place by gravity and does not need the action of gas thrust from inside the chamber. The device according to The present invention, therefore, works based on the temperature instead of the internal gas pressure, with speed and simplicity of opening.

Following the removal of the structure closing, the device releases an opening that has a section wide, which allows to release large amounts of flue gases and quickly decrease the pressure in the containment chamber, without generate dangerous overpressures.

The device according to the invention does not require high coupling accuracy; in fact, they are not provided shaft-hole type coupling that could easily adhere, but flange joints that are simple and Economical to prepare and assemble. In fact, the device can be removed by threaded connections that can be removed and, therefore, it does not require cuts to destroy sheets or parts welded

Therefore, the device is economical of prepare and assemble as well as maintain; in particular no you need to melt the metal material at the site, a procedure that would involve considerable risks and that would complicate the stages final assembly and maintenance.

In addition to this, the device according to the present invention may advantageously also be mounted in containers of existing explosives; in fact, it is enough to apply the device to an opening obtained or prepared in a wall of closure of the containment chamber.

Therefore, the device according to the present invention can be produced, installed, maintained and inspected at a low cost in terms of labor, material and equipment.

Claims (25)

1. A safety device (4) for containers (8) of explosive substances, said means comprising containers (8) a hydraulically accommodated chamber (12) sealed for an explosive substance bounded by at least one closing wall 16, said closing wall (16) having an opening (20) purge; the device (4) comprising at least one closing structure (28) suitable for sealing said closure purge opening (20), - the device comprising means of retention (34, 38, 42) mechanically separated from the structure (28) of closure and that are suitable to strengthen the structure (28) of closure in the purge opening (20), wherein said means (34, 38, 42) of retention include: - a fusion element (38), suitable for melt in order to release the closing structure (28) in case of exceeding a predetermined temperature threshold below of the explosive conditioning temperature, said fusion element (38) in an assembled configuration that at least partially interferes with the closing structure (28) to prevent the removal of the closing structure (28) of the containment chamber (12), characterized because the retention means (34, 38, 42) comprise additionally a splice element (42) which, in a configuration assembled, interferes with the fusion element (38) in order to lock the melting element (38) in a position against the closure structure (28), wherein said fusion element (38), in an assembled configuration is previously introduced in compression between the splice element (42) and the structure (28) of closing, in which the drain opening (20) has a shape axial symmetric relative to an axis (X-X) and the closure structure (28) has an external shape corresponding to the internal form of said purge opening (20), in which the fusion element (38) has a ring shape, so that in an assembled configuration it is axially symmetric relative to the axis (X-X) of the opening (20), in which the fusion element (38), in a assembled configuration, is previously introduced in compression between the splice element (42) and the closing structure (28), along an axial direction parallel to said axis (X-X) of the opening (20). 2. Safety device (4) according to the claim 1, wherein said splicing element (42) comprises a first plate (48) suitable to exert an influence on the compression of a portion of the contact melting element (38) with the closing structure (28). 3. Safety device (4) according to the claim 2, wherein said first plate (48) has a shape similar to the shape of the closing structure (28), so that it has external global dimensions smaller or equal to overall dimensions of the closing structure (28). 4. Safety device (4) according to claim 2 or 3, wherein said first plate (48) is mechanically secured to the closing structure (28) by securing means that can be secured
remove. 5. Safety device (4) according to the claim 4, wherein said securing means they comprise connections that can be removed from threaded type (52). 6. Safety device (4) according to the claim 4 or 5, wherein said securing means they comprise spacer bearings (56) arranged between the first plate (48) and closing structure (28). 7. Safety device (4) according to a any of claims 2 to 6, wherein it is provided a bleed valve (60) between the first plate (48) and the closure structure (28), suitable for intercepting gases from the containment chamber (12) and eject them out of said chamber (12) when a pressure limit value is exceeded. 8. Safety device (4) according to a any of the preceding claims, wherein said splice element (42) comprises a second suitable plate (64) to exert an influence on the compression of a portion of the melting element (38) in contact with a portion of said wall (16) closing. 9. Safety device (4) according to the claim 8, wherein said first and second plates (48, 64) They are mechanically separated from each other. 10. Safety device (4) according to a any one of claims 2 to 9, wherein said element (38) of fusion comprises at least one guide rib (68) suitable to facilitate the placement of the fusion element (38) in relation to at least one of the closing structure (28) and the First plate (48). 11. Safety device (4) according to a any of the preceding claims, wherein said melting element (38) comprises an alloy of bismuth-tin, which has a melting point between 135 ° C and 145 ° C. 12. Safety device (4) according to a any of the preceding claims, wherein said fusion element (38) comprises an eutectic alloy of bismuth-tin, which has a melting point equal to 138 ° C. 13. Safety device (4) according to a any one of claims 1 to 10, wherein said element (38) of fusion comprises high density polyethylene (HDPE) which It has a melting point equal to 135 ° C. 14. Safety device (4) according to a any of the preceding claims, wherein said fusion element (38) is a ring that has a relationship dimensional between a radial thickness and an axial thickness greater than or equal to one. 15. Safety device (4) according to claim 11, wherein said dimensional relationship is between 2 and 2.5. 16. Safety device (4) according to a any one of claims 1 to 15, wherein the structure (28) closure is made of aluminum. 17. Safety device (4) according to a any one of claims 1 to 16, comprising means (74, 76) suitable sealing to ensure hydraulic sealing Hermetic chamber (12) containment. 18. Safety device (4) according to the claim 17, wherein said sealing means comprise the minus an O-ring (76) disposed between the closing wall (16) and the closing structure (28). 19. Safety device (4) according to claim 17 or 18, wherein said sealing means they comprise at least one o-ring arranged between the structure (28) closure and the fusion element (38). 20. Safety device (4) according to a any one of claims 1 to 19, comprising a flange (80) suitable for insertion into the purge opening (20) and for housing at least partially the closing structure (28), with the in order to close hermetically, together with the structure (28) of closure, the purge opening (20). 21. Safety device (4) according to claim 20, wherein said flange (80) comprises a fixing clamp (84) suitable to form a joint against the closing wall (16) in the insertion of the flange (80) in the opening (20) and to allow fixing the flange (80) to said closing wall (16). 22. Safety device (4) according to claim 21, comprising at least one sealing ring (76) of the O-ring type between said clamp (84) and the wall (16) of closing. 23. Safety device (4) according to claims 20, 21 or 22, wherein said flange delimits a second housing (86) to accommodate said element (38) of fusion. 24. Explosive container (8), comprising a chamber (12) containing explosive material bounded by at least one closing wall (16), said closing wall (16) having a purge opening (20), the container (8) being characterized in that it comprises a safety device (4) according to any one of claims 1 to 23. 25. Method for preparing a container (8) of Safe explosives, comprising the stages of: - make a drain opening (20) in a wall (16) closing chamber (12) material containment explosive, - hermetically insert a device security in said purge opening (20) according to any one of claims 1 to 23.