DE102010022982B3 - Pressure-increasing explosive charge and ammunition containing this charge - Google Patents

Abstract

Proposed are multi-shell blast active charges and shaped charges or hollow charge-like shaped explosive charges, in which metal carbonyls in the form of pure substances, granules, blends with inorganic fuels or as granules of blends with inorganic fuels are integrated into corresponding closed containers. The metal carbonyls are used in the form proposed here as fuels, which in the intended implementation of the total charge an undirected (multi-shell blast active charges) or at least partially directed (hollow charges or hollow charge-like shaped explosive charges) have pressure-enhancing effect.

Description

The present invention relates to the use of metal carbonyls in highly explosive multi-shell explosive charges, hereinafter also referred to as Blast effective charges, and their preferred use in steered or unguided decoy ammunition or missile ammunition.

The present invention also relates to the use of metal carbonyls in hollow charges or explosive charge shaped explosive charges, the use of which is expressly not limited to use in guided or unguided dropping or guided munitions.

In recent decades, changed application scenarios have led to the development of various concepts based on novel explosives and explosive formulations and / or novel construction to increase the blast effect.

Part of the development focuses on the addition of inorganic fuels to explosive formulations. The performance enhancing supplement of fuels such. B. aluminum powder to explosive formulations has long been known. In addition to the height of the fuel component of a blend whose blast performance by the quality of the fuel (grain size, surface, etc.) and / or the admixture of other additives such. As inorganic oxidizing agent can be influenced.

Diverse investigations are aimed at the development of corresponding blast active charges using nanoscale powder grades of inorganic fuels or fuel blends with particle diameters smaller than 1 micron to accelerate the reaction. The problem of the reaction inhibiting oxide layer of such powders (boron and many light metals) and preventing the passivation of reactive metal surfaces makes the addition of corresponding excipients in the respective mixtures, possibly by appropriately upstream coating process, usually necessary. As examples of such additives, fluorine-substituted organic binders or ammonium perchlorate may be mentioned as the inorganic oxidizing agent. In addition to the function of a binder, fluorine-substituted polymers also serve as coating agents and as activators of the fuels, since their reaction forms at least traces of hydrogen fluoride which decompose the passivating oxide layer of the fuel powders. In the same way, it is also to be assumed that the ammonium perchlorate, which is frequently used as the oxidizing agent (eg. US 5,996, 501 A . US 6,955,732 A and US 6,969,434 A ) additionally acts as an activator by the liberated during the reaction of hydrogen chloride.

By circumventing the aforementioned problems, the with DE 10 2006 030 678 B4 proposed explosive charge based on red phosphorus as inorganic fuel is a blast active charge with very high pressure-volume work.

If the use of increasingly finer metal powder - possibly in conjunction with the above-mentioned additives - leads to explosive formulations with ever higher peak pressure outputs (cf. 2 in WO 2009/145926 A1 , should ultimately be achievable with an atomic fuel distribution a corresponding, dependent on the respective fuel, maximum power.

The present invention is based on the idea to generate multi-shell blast explosive charges using metal carbonyls as fuel. For this purpose, the less thermally stable metal carbonyls, especially iron pentacarbonyl, should be suitable in the first place. The pressure-enhancing effect should therefore be due to the fact that these compounds should decompose in detonative excitation in the respective atomically finely distributed elemental metal and the corresponding equivalents of carbon monoxide.

With particle diameters of 50 nm to 1 .mu.m, in nanoscale fuel powders, depending on the respective atomic diameter, contain several hundred to several thousand atoms per particle, which are possibly still surrounded by a passivating oxide layer. In contrast to this, atomic finely distributed fuels should be able to be generated in situ from the metal carbonyls by detonative excitation, so that a correspondingly increased mass conversion should lead to a significantly increased blast effect.

In addition to the finer fuel distribution, the latent problem of the passivating oxide layer in the case of nanoscale fuels or fuel mixtures is unnecessary when using the metal carbonyls.

The simultaneous release of atomically finely divided metal associated with a detonative excitation of the metal carbonyls and a number of gaseous equivalents of carbon monoxide corresponding to the respective composition should make a corresponding contribution to the pressure-volume work of the multi-layered blast active charge. Depending on the structure and composition of the explosive-containing shells proposed here multi-layer explosives (including dependence on the oxygen balance and the nature of the ingredients and reaction products), it is also conceivable that the suddenly released carbon monoxide itself continues to explode explosively with the primary burst of detonation.

Depending on the chemical-physical properties of the particular metal carbonyl to be considered, other reaction mechanisms are also conceivable. Irrespective of the respective conversion mechanism, in any case a release of energy which increases the efficiency of the blast active charge can be expected.

Of the known metal carbonyls, those of the iron, especially iron pentacarbonyl, may be considered as potentially suitable metal carbonyls. The great advantage of using iron pentacarbonyl is likely to be that this compound due to their use u. a. in the field of organometallic catalysts in appropriate quantities available from industry. In addition to diisone nonacarbonyl and triene dodecacarbonyl, in particular chromium hexacarbonyl, u. a. due to its temperature stability, be of interest. The use of all other existing, not only in matrix isolation experiments proved, metal carbonyls, especially those of molybdenum, tungsten, manganese and cobalt is hereby expressly not excluded.

Proposed are multi-shell - two- or three-shell - built Blast active charges and shaped charges or hollow charge-like explosive charges in which metal carbonyls are integrated in the form of pure substances, granules, mixtures with inorganic fuels or granules of mixtures with inorganic fuels in corresponding closed containers , The metal carbonyls are used in the form proposed here as fuels, which in the intended implementation of the total charge an undirected (multi-shell blast active charges) or at least partially directed (hollow charges or hollow charge-like shaped explosive charges) have pressure-enhancing effect.

Reference to an embodiment with drawing, the invention will be explained in more detail.

It shows:

1 a schematic sectional view of a two-shell constructed explosive charge with external or internal container filled with Metallcarbonyl container,

2 a schematic sectional view of a three-shell constructed explosive charge with external or internal container filled with Metallcarbonylem.

In the 1 as well as 2 indicated explosive charge 10 . 10 ' is with 1 an HE-burster and initiation charge. With 2 respectively. 4 the metal carbonyl or metal carbonyl granules or metal carbonyl-containing mixtures or granules are numbered. These are from a container wall 3 enclosed.

In a bivalve structure of the total charge ( 1 ) serves the shell of a compressible, castable or meltable explosive formulation existing shell as an initiation charge. This can be considered the central nuclear charge 1 be formed and is of a metal carbonyl 2 filled container 3 surround. Alternatively, this can be done with a metal carbonyl 2 filled container 3 ( 1 , right) also from a compressible, pourable or meltable explosive formulation 1 be completely or partially wrapped.

In a three-shell structure of the total charge ( 2 ) can do this with a metal carbonyl 4 filled container 3 as a central nuclear charge ( 2 , right) or outer shell ( 2 , left). This results in a corresponding arrangement of the remaining two, consisting of compressible, castable or meltable explosive formulations shells 1 . 5 ,

For the compressible, castable or melt-moldable explosive formulations to be used in the multi-shell explosive charges proposed here in addition to the metal carbonyls, all compostions established in corresponding ammunitions are suitable. There are no restrictions on the uniform explosives or explosives mixtures to be used, any binder matrices and any additives such as stabilizers, catalysts or processing aids. Furthermore, the explosive formulations to be used may contain additions of inorganic fuels and / or inorganic oxidizing agents up to 70% by weight, based on the particular explosive formulation itself. In a three-shell construction of the total charge beyond the possibility exists in the two explosives-containing shells different explosive formulations z. B. to achieve a graded gradient in terms of the fuel content or the oxygen balance, based on the total charge to use.

The metal carbonyls to be integrated in the form of closed containers in the form of closed multi-shell explosive charges may be used as a liquid in a pressure vessel (eg when using iron pentacarbonyl) or a correspondingly designed vessel as a loose or compacted powder bed (eg. B. at Use of diisone nonacarbonyl or trieisene dodecacarbonyl) or from a solid melted from a powder bed in a corresponding container (eg when using chromium hexacarbonyl). Furthermore, depending on the chemical-physical properties of the particular metal carbonyl to be considered, the use of, if appropriate mechanically compressible or compressible, metal carbonyl granules consisting of a metal carbonyl and a suitable binder in amounts of up to 10% by weight is not excluded. In addition, depending on the chemical-physical properties of the particular metal carbonyl, it is conceivable that it may be used to control the overall charge with up to 50% by weight of a metal powder in the form of a loose or compacted powder bed or in combination with a suitable binder (see above) to a maximum of 10% by weight) as compressible granules, to be mixed.

The proportion by weight of the metal carbonyl or optionally of the metal carbonyl-containing fuel mixture in one of the two- to three-shell explosive charges described here is from 10% by weight to 70% by weight, but preferably from 15% by weight to 45% by weight on the total charge. The proportion by weight of the conventional explosive formulations is accordingly between 30% by weight and 90% by weight, but preferably between 55% by weight and 85% by weight.

With regard to the use of the proposed blast active charges in modular thrown munitions or in missiles can be formed in the form of segmented body when using metal carbonyls as an outer shell, which can be stored separately and endlaboriert only before use. Alternatively, if iron pentacarbonyl is used as the metal carbonyl component, it would be possible to fill it by means of appropriate pumping systems only shortly before it is used in the already preloaded containers of the discharge ammunition designed in this way.

In addition to the use of metal carbonyls in undirected acting, multi-shell blast active charges also use in appropriately designed ammunition with at least partially directed blast effect or in shaped charges would be conceivable.

Using established explosive formulations as they are also used in other shaped charges, for example, by a conically shaped deposit container, which is then filled with a Metallcarbonyl, a partially directed, blast-enhancing effect or a performance-enhanced shaped charge could be generated (see performance-enhanced shaped charges through Lining them with reactive materials such as coruscatives). In particular, chromium hexacarbonyl should be suitable for this purpose, which itself decomposes explosively on rapid heating above 200 ° C.

Furthermore, it is conceivable that formed from the conically shaped container material in conjunction with optionally spontaneously and finely dispersed released during the implementation of metal, a shaped charge spike or projectile with respect to the pure container material performance (higher density, greater hardness). For shaped charges to be designed in this way, the metal carbonyls of other heavy metals, preferably those of molybdenum or tungsten, should also be particularly suitable.

In the manner described above, it should also be possible, if appropriate, to use shaped charges in which a layer of a thermic set, which releases the corresponding heavy metals elementarily, is installed between metal inserts and explosive. Compared with shaped charges constructed in this way, the shaped charges proposed here with metal carbonyl integrated in the deposit container should have the advantage that the release of the respective elemental heavy metal takes place more rapidly and in a comparatively finely distributed form, so that a shaped charge spike or projectile of higher quality should be formed.

The metal carbonyls to be integrated in the form of closed deposit containers proposed here in the form of hollow charge-like explosive charges can be formed as compacted powder bed or from a solid melted from a packed bed of powder in a corresponding container, depending on their chemical-physical properties (eg Use of chromium hexacarbonyl) are present. Furthermore, depending on the chemical-physical properties of the particular metal carbonyl to be considered, the use of mechanically compressible or compressible metal carbonyl granules consisting of a metal carbonyl and a suitable binder in amounts of up to a maximum of 10% by weight is not excluded.

The containers into which the metal carbonyls have to be integrated for the hollow charge-like explosive charges proposed here may be pointed or conical in shape. In addition, here are expressly no restrictions on the shape of the metal carbonyl-filled containers to achieve defined effects in the target. These include deposit containers that are designed with areas of different wall thicknesses to increase performance. In addition to copper as a container material, the use of other suitable container materials is not excluded.

The proportion of metal carbonyl to be incorporated in the correspondingly shaped deposit container may be between 5% by weight and 95% by weight, based on the total mass of container and of integrated metal carbonyl.

With respect to the explosive charge explosive charges proposed here, no limitations are imposed on the contained explosives or explosive mixtures, any binder matrices and any additives such as stabilizers, catalysts or processing aids. Furthermore, the explosive formulations to be used may contain additions of inorganic fuels and / or inorganic oxidizing agents up to 70% by weight, based on the particular explosive formulation itself.

Claims (29)

Multicellular blast active charge, consisting of a central core ( 1 . 2 . 4 ) and at least one, the core ( 1 . 2 . 4 ) surrounding shell ( 1 . 2 . 4 . 5 ), characterized in that a metal carbonyl as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel in the form of a closed container ( 3 ) is integrated. Hollow charge or hollow charge-like shaped explosive charge ( 10 . 10 ' ), characterized in that in this a metal carbonyl as pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel in the form of a closed container ( 3 ) is integrated. Multi-shell blast active charge or shaped charge or hollow charge-shaped explosive charge according to claim 1 or 2, characterized in that the metal carbonyl contained therein is one of the compounds listed below: Cr (CO) ₆ , Mo (CO) ₆ , W (CO) ₆ , Fe (CO) ₅ , Fe ₂ (CO) ₉ , Fe ₃ (CO) ₁₂ . Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that in a closed container ( 3 ) integrated metal carbonyl ( 2 . 4 ) is present as a pure substance as a function of its physicochemical properties as a liquid. Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that in a closed container ( 3 ) integrated metal carbonyl ( 2 . 4 ) as a pure substance depending on its physicochemical properties as a loose or compacted powder bed or as in the container ( 3 ) molten solid is present. Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that in a closed container ( 3 ) integrated metal carbonyl ( 2 . 4 ) is present as a compressible granules consisting of a metal carbonyl and a suitable binder in amounts up to a maximum of 10 wt .-% (based on this mixture). Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that in a closed container ( 3 ) integrated metal carbonyl ( 2 . 4 ) is present as a mixture with an inorganic fuel (up to 50 wt .-% based on the metal carbonyl), as a loose or compacted powder bed or as melted in the container solid. Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that in a closed container ( 3 ) integrated blend of a metal carbonyl ( 2 . 4 ) and an inorganic fuel as compressible granules, consisting of a metal carbonyl ( 2 . 4 ), an inorganic fuel and a suitable binder in amounts up to a maximum of 10 wt .-% based on this mixture is present. Multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to one of claims 1 to 3, characterized in that it is designed two- or three-shell, with one or two shells consists of one or two compressible, castable or meltable explosive formulations / exist and the remaining second or third shell is a metal carbonyl ( 2 . 4 ) in a closed container ( 3 ) as a pure substance, granules, Mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel contains. Blast active charge according to claim 1 and 3, characterized in that the core ( 1 ) may be formed as a central nuclear charge, which is a metal carbonyl ( 2 . 4 ) as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel filled container ( 3 ) is surrounded. Blast active charge according to claim 1 and 3, characterized in that the with a metal carbonyl ( 2 . 4 ) as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel filled container ( 3 ) of a bowl ( 1 ) compressible, pourable or meltable explosive formulation is completely or partially covered. Blast active charge according to one of claims 1, 3 to 9, characterized in that in a three-shell structure of the total charge that with a metal carbonyl ( 2 . 4 ) as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel filled container ( 3 ) is arranged as a central core charge or outer shell, wherein there is a corresponding arrangement of the remaining two, consisting of compressible, castable or meltable explosive formulations existing shells. Blast active charge according to claim 13, characterized in that the metal carbonyl ( 2 . 4 ) as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel filled container ( 3 ) is completely or partially enveloped by the shells made of compressible, castable or meltable explosive formulations. Blast active charge according to one of Claims 1, 3 to 14, characterized in that the proportion by weight of the metal carbonyl ( 2 . 4 ) as a pure substance, granules, mixing with an inorganic fuel or as granules of a mixture with an inorganic fuel based on the total charge between 10 wt .-% and 70 wt .-%, but preferably between 15 wt .-% and 45 wt. % lies. Blast active charge according to one of claims 1, 3 to 12, 15, characterized in that the weight fraction of the compressible, castable or meltable explosive formulation based on the total charge in a bivalve overall structure between 30 wt .-% and 90 wt .-%, preferably between 55% by weight and 85% by weight. Blast active charge according to one of claims 1, 3 to 9, 13 to 15, characterized in that the weight fraction of the compressible, castable or meltable explosive formulations based on the total charge in a three-shell total charge build-up in total between 30 wt .-% and 90 wt. -%, but preferably between 55 wt .-% and 85 wt .-% is. Blast active charge according to one of claims 1, 3 to 17, characterized in that the explosive formulations contained therein may contain additives of inorganic fuels and / or inorganic oxidizing agents in amounts of up to 70 wt .-% based on the respective explosive formulation itself. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, characterized in that the filled with a metal carbonyl as a pure substance, granules, blending with an inorganic fuel or granules of a blend with an inorganic fuel deposit container is pointed or flat conical shape. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, characterized in that filled with a metal carbonyl as a pure substance, granules, blending with an inorganic fuel or granules of a blend with an inorganic fuel deposit container a different from claim 18 form to achieve has a defined effect in the target. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, 19 to 20, characterized in that filled with a metal carbonyl as pure substance, granules, blending with an inorganic fuel or granules of a blend with an inorganic fuel deposit container with areas of different wall thicknesses is trained. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, 19 to 21, characterized in that the proportion of to be installed in the corresponding shaped deposit containers metal carbonyl as pure substance, granules, mixing with an inorganic fuel or granules of a mixture with an inorganic Fuel between 5 wt .-% and 95 wt .-% based on the total mass of Einlagenbehältnis and integrated Metallcarbonyl amounts. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, 19 to 22, characterized in that the deposit container made of copper or other suitable material. Hollow charge or hollow charge-like shaped explosive charge according to one of claims 2 to 8, 19 to 23, characterized in that the explosive formulations contained therein may contain additions of inorganic fuels and / or inorganic oxidizing agents in amounts of up to 70% by weight, based on the particular explosive formulation itself. Ammunition in the form of steered or unguided decoy ammunition or missile ammunition, characterized in that it contains a multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to claims 1 to 23. Ammunition in the form of steered or unguided rocket or gun ammunition, characterized in that it contains a multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to claims 1 to 23. Ammunition in the form of mortar or launcher grenades, characterized in that it contains a multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to claims 1 to 23. Ammunition in the form of shoulder verschiessbaren charges, characterized in that it contains a multi-shell blast active charge or hollow charge or hollow charge-like shaped explosive charge according to claims 1 to 23. Ammunitions in which multi-shell blast active charges or shaped charges or hollow charge-like shaped explosive charges according to claims 1 to 23 are integrated as submunitions or partial charges. Modular constructed ammunition constituting an ammunition according to claims 24 to 28 by retrofitting / laboratory of filled with a metal carbonyl as a pure substance, granules, blending with an inorganic fuel or granules of a mixture with an inorganic fuel closed containers.

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