BRPI0620007A2 - barrier, explosive device and vehicle - Google Patents

Abstract

BARRIER, EXPLOSIVE DEVICE, AND, VEHICLE. A passive barrier (10, 10 ', 10 ") configured to mitigate explosive waves and decelerate incident material to reduce the risk of sympathetic explosion of nearby explosive and / or damage to nearby objects. The barrier redirects the force of an incident explosive wave. and the incident materials.The barrier can be erected near explosive devices, inside vehicles carrying such devices or even outside the vehicle to protect you and personnel.The barrier can be configured to be interlocked with one or more barriers and It can be formed with a pedestal or placed on a stand to increase its stability.

Description

"BARRIER, EXPLOSIVE DEVICE, AND VEHICLE"

This invention relates to a barrier and, more particularly, a barrier suitable for diminishing the effects of an explosion.

It is known that if an explosive device is detonated, it may detonate another nearby explosive device by the effect of the generated explosive wave, and / or by the impact of fragments of the exploded item. In a situation where there are too many explosives or explosive devices in close proximity, it is essential to protect as many items as possible against the risk of being detonated by a nearby explosion.

After detonation of a device, there are three main mechanisms that can cause an explosion of another device, called a sympathetic explosion. Firstly, the explosive wave caused by the explosion of a first device can impact a nearby device with sufficient force to detonate or at least damage it. However, the explosive wave degrades rapidly, so that the risk of devices being detonated decreases rapidly with distance. Second, fragments of the exploded device and any nearby items may become projectiles radiating from the device. These fragments, called incident materials, can impact a device with enough energy to detonate the device. Fragments can also cause damage to the device that could make it unstable and vulnerable to detonation. Third, the explosive wave can lift and / or carry objects along its path, which thus become projectiles that can damage or detonate other devices.

It is known to use a barrier in a situation in which explosives are stored or where there is a possibility of an explosion occurring. These barriers can be reactive, for example reactive shield, or passive, which has no active components. Concrete has been employed in the past to constitute a passive barrier to withstand the destructive force of an explosion, such as the detonation of a bomb. However, barriers made of concrete are time consuming to build and, once built, are permanent. In a conflict situation, for example, explosive devices such as missiles need to be moved around and therefore. Constructed concrete barriers fall into disuse and other barriers need to be built elsewhere. Clearly, this practice requires a lot of time and material. One solution to this problem has been the use of water-loaded barriers. Water is well known in the art for mitigating explosions. A water-loaded barrier may comprise one or more water-charged containers placed between the explosive devices and the items to be protected. Containers overcome the previous problem as the barrier can be removed after use. However, the barrier needs to be erected where there is an adequate water supply. In an area where this supply is weak then the water to carry the containers also needs to be transported. Barriers are often bulky, which can be transport problems and increase their cost of use. Also, loading and emptying the containers takes time before they are used. Once the barrier is in place, it will prevent shock waves and particulates from detonating nearby explosives by acting as a shield. However, there is a possibility that the explosion and resulting explosive waves could move this barrier and cause it to impact the item being protected, which could result in physical damage to the item which could cause it to explode.

It is an object of the present invention to provide a barrier that is quick and easy to put in and remove from place, and which provides a suitable shield against an explosion and which does not become a projectile capable of detonating an explosive device in the event of an explosion.

Accordingly, the invention provides a passive barrier to mitigate explosive waves and decelerate incident material to reduce the risk of sympathetic explosions, where the barrier is configured to redirect the force of an incident explosive wave and to reduce the momentum of any incident material so that Mitigating the effect of the explosive wave and / or incident material causes the barrier to break, thus becoming harmless as well. Fragmentation of the barrier means that when the barrier is moved by the force of the explosion, it will break into smaller pieces not heavy enough to detonate a nearby device as they will not have mass large enough to cause damage if they impact a device. .

While the invention may be employed in close proximity to explosives and explosive devices such as bombs and missiles, it is not limited to such use.

The barrier can be used to prevent an explosion from detonating other explosives or explosive devices by protecting such devices. For example, the barrier can be placed between missile projectiles on an aircraft, torpedoes on a submarine, between stationary vehicles carrying explosive devices or in civilian or military storage. The barrier can also be used in a vehicle to carry and / or store explosives. The barrier may additionally be used to surround a vehicle or vehicles to ensure protection thereof. These uses are purely illustrative and do not restrict the scope of use of the invention.

Advantageously, the first embodiment of the barrier comprises at least one layer of a shock absorbing material covered on at least two opposite faces with a robust material in normal use, but which is capable of fragmentation upon exposure to a explosion.

The shock absorbing material layer is advantageously a foam material and, more advantageously, a polyethylene foam. Even more advantageously, the layer is made of Plastazote® which is a closed cell cross-linked polyethylene foam produced by Zotefoams plc.

A suitable material for the layers covering the shock absorbing material is glass fiber, advantageously a high strength composite fiberglass, such as S2-glass®, used under license from Aerospace NP. This material is capable of disintegrating into harmless fragments when impacted, but is otherwise structurally rigid, making it an ideal material for barrier use.

The dimensions of the fiberglass layers are chosen to be strong enough to withstand the initial shockwave and to slow down the fragments resulting from an explosion. The barrier may be of such thickness as to prevent fragment piercing therethrough, but this is not an essential feature of the invention. The barrier can also be optimized to a thickness so that it cannot prevent all fragments from impacting the areas to be protected, but will slow them down to such a degree that the fragments do not have sufficient residual energy to cause damage resulting in additional detonation. Alternatively, the barrier may be optimized to prevent passage of all fragments. In all of these embodiments, the barrier provides adequate protection against fragment impacts. In a first embodiment, when the barrier is bombarded with fragments, it begins to delaminate. This delamination, then, means that the barrier itself does not pose a risk to adjacent ammunition, since the layers that make up the barrier are not heavy enough to cause impact damage.

Although the inventors do not wish to be limited by this theory, they believe that the first embodiment of the barrier works as follows. The shockwave is reflected by the composite fiberglass as there is a change in air density for the barrier, ie low density for high density. When the shockwave hits the rear face of the composite fiberglass, there is another reflection of the wave as there is another change in material density. Part of the remaining wave force may pass through the foam layer and the wave reflection process is restarted when the wave encounters the second composite fiberglass layer. Foam prevents one layer of fiberglass from reaching another layer of fiberglass with significant force after being impacted by an explosive wave by slowing down the first layer. If air were used as the low density layer, the first fiberglass layer would impact the second fiberglass layer.

In another embodiment, the barrier comprises a polyurethane layer surrounding a fiberglass layer S2, the fiberglass layer S2 may be comprised of an S2-foam-glass S2 glass structure as previously described. Impact resistant polyurethane foams are advantageous and commercially available from General Plastics. S2 polyurethane and glass layers will delaminate under the force of an explosion and / or impact by incident material.

In yet another embodiment, an explosion mitigating barrier may be formed entirely of an impact resistant polyurethane foam. This foam collapses on itself as it is impacted by explosion fragments and thus slows their passage. A preferred foam is LAST-A-FOAM®, produced by General Plastics.

In another embodiment, the barrier may be formed of an aluminum honeycomb structure. Such a structure is capable of slowing down explosion fragments as much energy is absorbed in the fracturing of such a hive structure. This embodiment has the advantage that the barrier is relatively low in mass, so it is not possible for it to transmit sufficient energy when impacted to detonate an explosive device, but capable of slowing down explosion fragments.

The thickness of the layers used can be optimized for your particular use. It is desirable to have a balance between the barrier being thick enough to adequately perform its function, but having a minimum mass so as not to cause detonation if moved by the explosive wave to impact a device.

The shape of the barrier can be selected to direct shock waves and blast fragments in a particular direction. One skilled in the art would know how to do this within the constraints of the geometry of a given situation. Such shapes may be, for example, substantially flat, curved, cylindrical or diamond shaped. The barrier may be of any size which provides protection and is capable of being easily moved and carried. If a longer barrier length or height than a single barrier is required, then a plurality of barriers may be placed side by side and / or one above the other until the desired length and / or height is reached. In another advantageous embodiment of the invention, the barrier is configured so that it can be interlocked with other barriers of the invention. This will be achieved by any suitable means such as tongue and groove formations, dovetail joints or finger joints over the edge of the barrier. This feature gives the user the option to build a longer and / or taller barrier that may be better suited for use in environments where a large area needs to be protected, for example when separating aircraft missiles or providing a partition wall. between storage of explosive materials.

The barrier can be formed with one foot so that it can stand without support. Alternatively, it may be placed on a support to ensure stability or it may be suspended near the item to be protected, for example from the underside of an aircraft wing. The pedestal, support or suspension may be made of any suitable material which may also have explosion attenuation properties. The pedestal, stand or suspension can also be weighed if necessary to provide greater stability.

The present invention will now be described with reference to the following drawings:

Fig. 1 shows a profile view of a first embodiment of the invention.

Fig. 2 shows a profile view of a second embodiment of the invention.

Fig. 3 shows a profile view of a third embodiment of the invention.

Fig. 4 shows the barrier of fig. 1 and 3 in use in a military situation.

Fig. 5 shows a plan view of another embodiment

of the invention.

In an advantageous embodiment as shown in fig. 1, it can be seen that the barrier 10 comprises multiple layers 12 and

14. Layers 12 and 14 are held together with fasteners, such as glue or clips, that maintain the integrity of the barrier prior to its exposure to an explosion, but which does not prevent the barrier from delaminating in the event of an explosion. Layer 12 is made of S2® glass panels and layer 14 is made of Platazote®.

Fig. 2 shows the barrier 10 'in a curved configuration formed to provide greater protection to an explosive device, D, or the surrounding area. If device D is the item to be exploded, the explosion will be partially contained by the curved nature of barrier 10 '. If device D is already the item to be protected, then it will be protected from explosions directly to its left (as shown in the figure) and also partially above.

Fig. 3 shows barrier 10 "in another curved configuration, wherein the barrier houses at least a portion of the explosive device D. Such a configuration is useful where explosive devices are in close proximity to each other, for example in an aircraft or torpedo storage .

Fig. 4 shows the barrier of the invention in use in a military situation. Barrier 10 is placed under the fuselage of an airplane 20 between missiles 16. Other barriers 10 are placed between neighboring missiles on the aircraft. Missiles 18 on the wing end of the aircraft are housed by barriers 10 "having a curved configuration that follows the contours of the device to be protected. Other barriers may be placed adjacent to the aircraft to protect neighboring objects such as other aircraft, missiles, areas / storage or personal environments 26.

Fig. 5 shows another embodiment of the barrier comprising a polyurethane layer 50 on opposite faces of an S-2 52 glass layer. The polyurethane layers are triangular in shape to deflect the explosive wave and blast fragments (shown by arrows) to away from device D to be protected. In fig. 5, both polyurethane layers are triangular in shape, providing protection to the devices at each end over the apex should one of the devices be detonated.

Although a layered barrier is shown in the drawings, a barrier comprising five or more layers is also possible.

While the characteristic of the barrier being movable is important, it is also envisaged that the barrier may be permanently attached or movable in place by any suitable means to provide protection.

Attempts have been made that a sympathetic explosion of a general purpose bomb of about 500 kg can be mitigated with a shelter barrier (shown in the figures by 10 ") comprising two outer layers of 15-20 mm fiberglass laminated over 12". -15 mm cross-linked, closed-cell polyethylene foam The weight of a 1350 x 340 mm x 60 mm panel is 50 to 60 kilos.

Barrier technology has been proven to protect a 155mm projectile behind the barrier of FIG. 1 to be detonated sympathetically by detonating a 155 mm projectile on the other side of the barrier.

Claims (18)

1. Passive barrier to mitigate explosive waves and decelerate incident material to reduce the risk of sympathetic explosions, characterized in that the barrier is configured to redirect the force of an incident explosive wave, to reduce the momentum of any incident material so that the mitigation of The effect of the explosive wave and / or incident material causes the barrier to break, thereby rendering it harmless. Barrier according to claim 1, characterized in that the barrier comprises at least one layer of a shock absorbing material covered on at least two opposing faces by a material capable of fragmentation. Barrier according to claim 2, characterized in that the shock absorbing material is a foam. Barrier according to Claim 3, characterized in that the foam is a polyethylene foam. Barrier according to Claim 4, characterized in that the foam is an expandable polyethylene foam. Barrier according to any one of claims 2 to 5, characterized in that the disintegrating material is fiberglass. Barrier according to claim 1, characterized in that it comprises one or more layers of polyurethane foam. Barrier according to claim 7, characterized in that the polyurethane foam is an impact resistant polyurethane foam. Barrier according to claim 7 or 8, characterized in that there is a layer of fiberglass on or between one or more layers of foam. Barrier according to any preceding claim, characterized in that the barrier is further configured to be interlocked with one or more barriers. Barrier according to any preceding claim, characterized in that the barrier is substantially flat. Barrier according to any preceding claim, characterized in that at least part of the barrier is curved. Barrier according to any preceding claim, characterized in that the barrier is held in position by means of a pedestal, support or suspension. 14. Barrier, characterized in that it is substantially as described above with reference to the accompanying drawings. Plurality of barriers according to any preceding claim, characterized in that the passage of all fragments is prevented. 16. Barrier, which comprises an aluminum honeycomb structure for decelerating fragments of a detonated device to reduce the risk of sympathetic explosions and configured to have a minimum mass that is not suitable for detonating a nearby explosive device. Explosive device, characterized in that it comprises a barrier as defined in any one of claims 1 to 16. Vehicle, characterized in that it comprises a barrier as defined in any one of claims 1 to 16.