FR2674620A1 - Explosive device, especially for bombs - Google Patents

Abstract

The invention relates to explosive devices. It relates to a device in which the load (5) is distributed into an internal load (5b) and an external load (5a) separated by an internal cup-shaped region (7) of a material containing a metallic fuel. A device (13, 15, 17) ensures the ignition of the charge on both sides of the internal bowl while the powerful explosive material is in contact preferably on both sides of the material containing the metallic fuel. Application to bombs and load cones.

Description

The present invention relates to explosive devices.

  Ammunition using the breath as an agent

  have been used for many years. They range from bombs used for external and internal deterioration of weak targets to charge cones used for attacking ships and ships.

aircraft and explosive shells.

  However, these munitions have well-known restrictions, the main one being that the

  overpressure caused by the breath decreases very rapidly

  from the moment of detonation, so precise positioning is paramount unless a curtain attack is possible, as in the case of bombs and shells. In addition, the loss of efficiency at high altitudes is important Very often, the fragmentation metal envelope placed around a load cone contributes

  more to the deterioration of the target than the breath itself

  even. Nevertheless, the breath has a certain role to play in

  weapons systems of the future, especially if we can

  improve their efficiency without increasing their overall mass. Conventionally, the amplitude and the duration of a blast wave, that is to say of the overpressure, given by a munition filled with a powerful explosive such as RDX / wax, are increased by addition of about 20% by weight of aluminum powder Additions exceeding 20% are not practical in practice for two reasons First, the reduction in detonation velocity caused by the addition of aluminum which is inert is non-explosive,

  reduces the effectiveness of breakage and fragmentation

  Then the oxidation of aluminum introduces side reactions with the detonation products, some of which cause a reduction in the overall volume of gas produced in the explosion.

  heat of explosion Q increases in proportion to aluminum

  As a result, the volume V of gas decreases, so that the "characteristic product" Qx V, on which the working capacity or the power depends, reaches a maximum value for about 20% of aluminum. An explosive device comprising a charge of a strong explosive material, an inner zone or wall, placed in the explosive material, formed of a material comprising a metal fuel, and a device for initiating the explosive material. opposite sides of the zone or wall, the explosive material

  at least one side of the zone or wall containing a material

  additional material that includes a metal fuel

  or being in contact with such material.

  The zone or wall may be in the form of a plate or a grid However, it is preferable that an enclosure is formed around a cylindrical zone or in the form of a series of parts which together correspond

  approximately to an enclosure formed around the confi-

  cylindrical structure, so that the explosive material is divided inside and outside the enclosure into inner and outer zones constituting the sides of the zone

or wall.

  The additional material may be a powdered metal fuel dispersed in the explosive material, and / or an outer shell, in which the explosive material is placed, may be formed of a material containing

a metal fuel.

  The device according to the invention may comprise

  several areas or walls that are substantially cylindrical

  driques incorporated into the explosive material.

  The operation of the device according to the invention is the following When the explosive material placed on both sides of the zone or wall is primed, an explosive blast

  is applied against the zone or wall.

  associated with the explosion of an explosive material

  However, ignition and combustion of the metal fuel in contact with the charge allows maintenance of the pressure wave for a time of up to several milliseconds. This is usually propagated in the material in microseconds.

  additional metal fuel allows the hand-

  a wave of implosion pressure produced after charging the charge, applied to the zone or wall and causing ignition of the metal fuel of the zone or wall, such that a concentrated internal source of a metal fuel that burns is formed and the effect

  overall blast of the charge is increased.

  This configuration has a number of advantages The detonation properties of the powerful explosive are not affected by the addition of the metal in the zone or wall; the metal is subjected to high pressures and temperatures by implosion, and thus causes a satisfactory ignition of the combustion, and, if an oxidizer is to be used, it can be introduced as

  component, by implementing a process of im-

  mixing and reaction, so that it is no longer necessary to produce thoroughly mixed mixtures consisting of an explosive, a fuel

an oxidant.

  The metal fuel of the material of the zone or wall may be aluminum but it is preferably a metal or mixture of metals having a high heat of

  combustion, for example selected from one or more

  boron, beryllium and lithium.

  The metallic material may also be selected from

  magnesium, titanium, zirconium and their mixtures.

  It is better to use boron as

  Metallic surface or boron metal may be in elemental form but may also be in the form of an alloy or compound with other elements. It may be in the form of a pyrotechnic composition, in cooperation with other exothermic materials, for example one or more of the other specified metals The material containing the metal fuel, for example the boron-containing material, is preferably in the form of

  It can for example be arranged as a

  charging material directly into the explosive charge, for example in the form of powdered or sintered boron, or it may be placed in a suitable solid envelope disposed in the explosive charge or may be embedded in a binder, for example a plastics material which may to be a binder

  fuel with a large amount of energy such as nitro-

  cellulose. An oxidant, for example a mineral nitrate such as potassium nitrate, may optionally be added, for example in an amount up to 20% of the weight of the material constituting the metal fuel of the zone

or wall.

  When the metal fuel is boron, the

  This invention is a particularly advantageous method of using boron as a metal fuel.

  that boron is very reactive and has an incompatibility

  long-term stability with powerful explosives and can

  give high sensitivity to these powerful explosives.

  It is also very difficult to prime. As a result, boron can not be used as a metal fuel in an intimate mixture with strong explosives of the same kind.

  aluminum powder is used in a number of

some applications.

  The present invention enables the resolution of

  These areas, when it contains boron, permit the separation of boron from the explosive material. In addition, the heat generated by the combustion of the additional material containing a metal fuel makes it possible for the boron to be separated from the explosive material. the initiation of boron by the implosion mechanism

previously described.

  The metal fuel of the additional material containing the metal fuel is preferably aluminum, for example in elemental form or in the form of a compound. The strong explosive material placed on one or both sides of said zone or wall may, for example The charge can advantageously be placed in an outer envelope of aluminum. For example, such an envelope is usually formed of low density aluminum foam. The explosive device according to the invention can be of any of the types of devices in which a powerful explosive detonates so that it gives a breath, for example in the form of ammunition such as bombs, cones of charge, shells , projectiles, bombs,

mines and the like.

  According to its construction and its method of use

  tion, the device according to the invention can detonate in the air

  free or under water where appropriate In general,

  metals burn in the air or in

  detonation or in water or water vapor.

  The material of the explosive charge, in a

  According to the invention, the explosive material may be any suitable strong explosive which is well known to those skilled in the art. For example, the material may be made in a molten form or in a molded, compressed, rolled or extruded form, but is preferably a material

  powder or sintered containing a fine metal

  divided aluminum-containing It may for example

  contain a composition that contains one or more

  selected from TNT (2,4,6-trinitrotoluene), RDX (1,3,5-cyclotrimethylene-2,4,6-trinitramine), HMX (cyclo-1,3,5,7-tetramethylene-2), 4,6,8-tetranitramine), the

  ammonium perchlorate and ammonium nitrate, possibly

  other oxidants, binders, fillers or plastics

  such as polymers, plastics,

  waxes and body fluids, as they are commonly

  used in powerful explosive compositions.

  Preferably, said zone or wall has a dish-like structure within the charge and divides it into an inner region and an outer region. The dish-shaped structure and the charge may be placed in a shaped container. Bowl The end

  outer part of the bowl-shaped structure coincides practically

  only with the outer surface of the inner and outer regions of the load placed in the container, preferably. The inner and outer regions of the charge may be initiated by a ring of an explosive material, for example an explosive material known as a plastic sheet, deposited at the end of the dish-shaped structure and placed in contact with

  internal and external regions of the charge The ring of

  The explosive material may be initiated by a series of tracks of explosive material, for example an explosive material in the form of a plastic sheet, each of the tracks being placed outside the container and in contact with each other. a position among a series of

  equidistant positions circumferentially on the ring.

  Tracks can be initiated by an explosive primer

  may be triggered by an adjacent detonator

  The primer and the detonator can advantageously be arranged in the form of elements plugged into a cavity formed in a cap placed around the explosive ring, the tracks and a cable.

end of the container.

  The explosive material in the form of a ring leaf

  and tracks may be a known material with a binder of

  plastic material, for example a known material containing the following ingredients

RDX

  PIB (Polyisobutylene) DEHS (Diethylhexyl sebacate)

  and containing about 90% by weight of RDX.

  The explosive primer can be formed from a known mixture of RDX and a wax, for example containing 96% by weight

  RDX weight and 4% by weight of wax.

  Other features and advantages of the invention

  tion will become more apparent from the following description,

  Referring to the accompanying drawings in which: Figure 1 is a side elevation section of a stepped charge cone according to the invention; and FIG. 2 is a plan view of the load cone of

  Figure 1 (after removal of the cap).

  As shown in FIGS. 1 and 2, a charging cone comprises a bowl-shaped container 1 which delimits a substantially cylindrical region inside, the container 1 being formed of aluminum foam having a closed end 3 The container 1 is filled with a charge of a strong explosive material containing an oxidizing material intimately mixed with a metal fuel

  formed of an aluminum powder An internal bowl 7

  in the container 1 and the charge 5 is formed of a material containing boron optionally mixed with another metal fuel such as zirconium The inner cup 7 divides the charge 5 into an inner region Sa and an outer region 5 b L ' open end of the inner bowl 7 substantially coincides with a surface 9 of the load 5 facing the outside of the cylinder 1 The surface 9 is placed in the container 1 A ring 11 of annular section formed of an explosive material sheet is deposited at the surface 9 and covers the outer end of the bowl 7 and is in contact with the inner region Sa and the outer region 5b of the load 5 A series of explosive tracks 13 (also shown in Figure 2) formed of a foil of explosive reach different points of the ring 11 from a single primer 15 placed outside the container 1 The primer 15 is triggered by an adjacent detonator 17 wire bridge who

  can be controlled by a known wick (not shown).

  The thickness of the ring 11 is substantially equal to the length of the container 1 beyond the surface 9 of the load 5 An additional ring 19 is placed between the ring 11 and the container 1 so that the space between Finally, an outer metal cap 21, shown in Figure 1 but removed in Figure 2, is placed on the tracks 13, the rings 11, 19 and the open end of the container 1 The cap 21 has a cavity in which the primer 15 and the detonator 17 are advantageously placed. During operation, the detonator 17 controls the primer 15 and causes the launching of a shock wave that travels along the tracks 13 and reaches the regions

  internal and external 5a and 5b of the load 5 via

  ring at almost the same time.

  5, the implosion is fed by the aluminum contained in the explosive material of the charge 5 and in the container 1. The internal cup 7 plays the role of a concentrated source of boron is thus ignited and the very exothermic combustion of boron increases

  the overall blast effect of the load cone.

  In one variant of the invention, several internal cuvettes may be present and may contain boron in the charge 5, the charge being thus divided into more than two regions. In this case, the ring of the explosive sheet covers both cuvettes and is in contact with all

regions of the charge.

Claims (18)

  1 Explosive device, characterized in that it comprises a charge (5) of a strong explosive material, an inner zone or wall (7) of a material containing a metal fuel and incorporated into the explosive material, and a device (13) , 15, 17) for priming the material   explosive on both sides of the zone or wall, the material   explosive material on at least one side of the zone or wall containing   an additional material that contains a combustible   metal or placed in contact with such material.   2 Device according to claim 1, characterized in that the zone or wall (7) is an enclosure placed around a cylindrical zone or in the form of a series of parts which correspond together approximately to one   placed around a cylinder, so that the material   explosive material is distributed inside and outside the enclosure, in the internal and external zones constituting the sides of the area or wall.   3 Device according to one of claims 1 and 2,   characterized in that the additional material is a powdered metal fuel dispersed in the explosive material or is an outer shell or is in both forms, the envelope containing the explosive material and being   formed of a material that contains a metal fuel lic.   4 Device according to any one of the claims   tions, characterized in that it comprises   several zones or walls (7) of substantially cylindrical shape   drique, incorporated into the explosive material.   Device according to any one of the claims   in which the metal fuel of the material of said zone or wall (7) is selected from one or   several metals in the group that includes boron, beryl   lium, lithium, magnesium, titanium and zirconium.   Device according to claim 5, characterized in that the metal fuel of the zone or wall (7) contains elemental boron or an alloy or   of a compound formed with other elements.   Device according to claim 6, characterized   in that the boron is in the form of a pyrolysis   technique with other exothermic materials.   8 Device according to claim 6, characterized in that the material containing boron is in the form a powder.   9 Device according to claim 6, characterized in that the material containing boron is embedded in a binder.   Device according to any one of the claims   in which an oxidant is added in an amount up to 20% of the weight of the material containing the metal fuel of the zone or wall (7).   11 Device according to claim 10, characterized   in that the oxidant is a mineral nitrate.   12 Device according to any one of the claims   tions, characterized in that the fuel   additional material containing a fuel metal is aluminum.   13 Apparatus according to claim 12, characterized   in that the strong explosive material on one or both sides of the zone or wall (7) contains the aluminum powder.   Apparatus according to claim 12, characterized   in that the load (5) is arranged inside   an outer envelope of aluminum.   Device according to claim 14, characterized   rised in that the envelope is formed of aluminum foam low density.   Apparatus according to any one of the claims   characterized in that said zone or wall (7) has a cup shape placed in the load and dividing it into an inner region and an outer region.   Apparatus according to claim 16, characterized   it is susceptible in that the charge (5) is placed in a dish-shaped container, and the outer end of the dish-shaped structure substantially coincides with the outer surface of the inner and outer regions of the charge placed in the container .   Apparatus according to claim 17, characterized   in that the inner and outer regions (5a, 5b) of the charge are initiated by a ring (11) of explosive material deposited on the end of the dish-like structure and placed in contact with the regions internal and external of the charge.   19 Apparatus according to claim 18, characterized   in that the ring (11) of foil-shaped explosive material is initiated by a series of tracks (13) of explosive material, each track being placed outside the container and in contact with a location of a series of equidistant locations circumferentially on the ring.   Device according to claim 19, characterized   in that the tracks (13) are initiated by a common primer (15) to be triggered by a detonator adjacent (17).   21 Apparatus according to claim 20, characterized   characterized in that the primer (15) and the detonator (17) are arranged as members which can be introduced into a cavity formed in a cap mounted on the ring   explosive and the tracks and on one end of the container.