FR2999568A1 - EXPLOSIVE LOAD WITH PRESSURE AMPLIFICATION - Google Patents

Abstract

The invention relates to a multi-envelope blast-active filler in which a metal carbonyl, in the form of a pure substance, granules, a mixture with an inorganic fuel or granules of a mixture with an inorganic fuel, is integrated. in the form of a container (3) closed.

Description

The present invention relates to the use of metal carbonyls in multi-envelope detonating explosive charges, referred to herein as "blast active charges", as well as their preferential use in munitions dropped with or without guidance or in ammunition for guided weapons. The present invention also relates to the use of metal carbonyls in hollow charges or explosive charges shaped hollow charges, their implementation is not limited to ammunition released with or without guidance and ammunition for guided weapons. The evolution of combat scenarios in recent decades has led to the development and development of very diverse concepts based on new explosives and explosive formulations and / or new construction to increase the effect of breath. Thus some of the developments focus on the addition of inorganic fuels in explosive formulations. The addition of performance-enhancing fuels, such as for example aluminum powder, in explosive formulations has been known for a long time. In addition to the proportion of fuel in a mixture, the quality of the fuel (grain size, surface area, etc.) and / or the addition of other products such as, for example, inorganic oxidizing agents, can influence its ability to breath. Various studies have focused on the development of adapted blast active charges using nanometric powder qualities for inorganic fuels, with particle diameters of less than 1 pin, to accelerate the reaction. The problem of the oxide layer inhibiting the reaction of such powders (for boron and many light metals) as well as the need to avoid the passivation of surfaces of the reactive metals, in general, makes it necessary to use of suitable adjuvants in the preparations, where appropriate by prior coating processes. As examples of adjuvants, mention may be made of fluoro-substituted organic binders or ammonium perchlorate as inorganic oxidant. In addition to the binder function, the fluoro-substituted polymers also serve as coating agents and fuels activators, since, during their transformation, at least traces of fluorinated hydrogen are formed which break down the layer. of passivating oxide of the fuel powder. In the same way, it can be supposed that ammonium perchlorate frequently used as an oxidizer (for example US Pat. Nos. 5,996,501, 6,955,732 and 6,969,434), because of the hydrochloric gas released during the reaction, acts as an activator. By avoiding the problems mentioned above, the red phosphorus explosive charge as an inorganic fuel disclosed in DE Patent Application 2006/030678 B4 represents an active blast load with a very high pressure-volume work. Since the use of ever thinner metal powder - possibly in combination with the added substances mentioned above - results in explosive formulations with ever higher maximum pressures (see Figure 2 of the patent application WO 2009 / 145926 A1) it should be possible to obtain in the end, with an atomic fuel distribution, a corresponding maximum power dependent on the fuel used. The idea underlying the present invention is to produce multi-envelope blast explosive charges using carbonyl metals as fuels. For this purpose the less carbon-resistant carbonyls, with iron-pentacarbonyl at their head, should be suitable. The effect of pressure amplification is due to the fact that these compounds, during detonation excitation, decompose into elemental metal with an atomic distribution and the corresponding carbon monoxide equivalents. With particle diameters ranging from 50 nm to 1 μm, the nanometric fuel powders, depending on the diameter of the atom concerned, contain from several hundred to several thousand atoms per particle which, where appropriate, are additionally surrounded by a passivating oxide layer. In contrast to this, it is possible to produce from the metal carbonyls, by detonation on site, fuels with a fine atomic distribution such that a larger mass reaction generates a considerably enhanced blast effect. In addition to the finer fuel distribution thus obtained, the latent problem of the passivating oxide layer in nano fuels or fuel mixtures disappears with the use of metal carbonyls. The release of metal with a fine atomic distribution and a quantity of gaseous carbon monoxide equivalents dependent on the composition which occurs synchronously with the detonation excitation of the metal carbonyls is partly involved in the pressure work. volume of the multi-envelope blast active charge. Depending on the structure and composition of explosive envelopes of explosive charges with multiple envelopes proposed here (in particular depending on the oxygen balance and the nature of the ingredients and reaction products) one can imagine that the carbon monoxide which is released suddenly then react explosively with the primary deflagration cloud. Depending on the physico-chemical properties of the metal carbonyl considered, other reaction-transformation mechanisms are also possible. Whatever the reaction-transformation mechanism under consideration, one must expect in all cases a release of energy that increases the power of the active blast load. Among the known metal carbonyls, those of iron and, first of all, iron pentacarbonyl, should be considered as potentially suitable metal carbonyls. The important advantage related to the use of iron-pentacarbonyl is that this compound, because of its use in particular in the field of organometallic catalysts, is available in sufficient quantities on the industry side. In addition to diferro-nonacarbonyl and triferro-dodecacarbonyl, chromium hexacarbonyl is of interest because of its temperature stability. The use of all other existing metal carbonyls, and not only those revealed in matrix isolation experiments, particularly those of molybdenum, tungsten, manganese and cobalt, is not expressly excluded here. It is proposed multi-envelope blast-active charges - two or three envelopes - as well as hollow charges or explosive charges shaped as hollow charges in which the metal-carbonyls are integrated in the form of pure bodies, granules, mixtures with inorganic fuels or granules of mixtures with inorganic fuels enclosed in suitable containers. The metal carbonyls, in the form presented here, serve as a fuel which, upon consistent conversion of the overall charge, has a non-directed pressure amplifying effect (multi-envelope blast active charges) or at least partially directed (hollow charges or explosive charges shaped as hollow charges). The invention is described in the following with the aid of an exemplary embodiment with reference to the drawings. These represent: FIG. 1, a diagrammatic sectional representation of a two-envelope explosive charge with a metal-carbonyl-filled container disposed outside or inside; Figure 2 is a schematic cross-sectional representation of a three-shell explosive charge with a metal-carbon-filled container disposed externally or indoors. In the explosive charge 10, 10 'shown in FIGS. 1 and 2, reference numeral 1 denotes an explosive charge of HE fragmentation initiation. Marks 2 and 4 denote the metal carbonyl or the metal carbonyl granules or the mass or even the granules containing metal carbonyl. These are surrounded by a container wall 3. In a two-shell construction of the overall load (FIG. 1), the envelope consisting of a pressure-formable, castable or melt-moldable explosive formulation serves as a boot load. This can be arranged in charge core 1 central and surrounded by a container 3 filled with metal carbonyl 2. As an alternative solution, the container 3 filled with metal carbonyl 2 (Figure 1, right) can also be surrounded, in part or in full, of a pressure-formable, castable or melt-moldable explosive formulation. In the case of a construction with three envelopes (FIG. 2), the container 3 filled with metal-carbonyl 4 is arranged as a central core load (FIG. 2, on the right) or as an outer envelope (FIG. 2, on the left). This results in a corresponding arrangement of the two remaining envelopes 1, 5, formed of an explosive formulation 1 that is pressure-formable, castable or melt-moldable. With respect to moldable, castable or melt moldable explosive formulations usable in addition to the metal carbonyls in the multi-jacketed explosive charges herein, all compositions established in the ammunition of interest may be used. There is no restriction on homogeneous explosives or mixtures of explosives, any matrices of binders or any adjuvants such as stabilizers, catalysts or processing aids. In addition, the explosive formulations that may be used may contain additions of inorganic fuels and / or an oxidizing agent in amounts up to 70% by weight, based on the explosive formulation concerned.

In a three-envelope explosive charge, it is possible to use different explosive formulations in the two envelopes containing the explosive, for example in order to obtain a gradual gradient in terms of the combustible part or the oxygen balance, reported to the overall charge.

The metal carbonyls to be integrated as closed containers in the multi-envelope explosive charges, depending on their physicochemical properties, may be in the form of liquid contained in a pressurized enclosure (for example in the case of iron pentacarbonyl ) or by means of a suitable container in the form of a bulk charge of uncompressed or compressed powder (for example in the case of diferro-nonacarbonyl or triferro-dodecacarbonyl) or a solid consisting of a bulk charge of powder molded in a suitable container (for example in the case of chromium-hexacarbonyl) Moreover, depending on the chemical-physical properties of the metal-carbonyl considered, it is not excluded to use compacted or compressed metal-carbonyl granules mechanically and composed of a metal carbonyl and a suitable binder, in amounts of up to 10% by weight maximum. In order to increase the power of the overall charge, it is necessary to mix the latter with up to 50% by weight of a metal powder in the form of a mass of uncompressed or compressed powder or granules obtained by compression with suitable binder (up to 50% by weight maximum). The weight share of metal carbonyl or metal-carbonyl-containing fuel mixture in one of the two or three-shell explosive fillers described herein is between 10 wt% and 70 wt%, preferably 15 wt%. weight and 45% by weight, based on the overall load. The proportion of conventional explosive formulations as a result of this is between 30% by weight and 90% by weight, preferably between 55% by weight and 85% by weight of the overall charge. With regard to the use of blast fillers in modular jettisoned munitions or guided missiles, when using metal carbonyls as the outer shell, it can be made as a segmented body. , whose segments can be stored separately and assembled at the time of use. Similarly, in the case of the use of iron-pentacarbonyl as the metal carbonyl component, it would be possible to load the latter into the containers already in place, by means of suitable pumping installations, shortly before the use of the dropped munition.

In parallel with the use of metal carbonyl in non-directed, multi-enveloped, blast-effect active charges, use in an adapted munition can be imagined with at least partially directed blast or in hollow charges. Using established explosive formulations, such as those used in other hollow fillers, one could for example use a cone shaped hollow charge coating container filled with metal carbonyl, generate a partially directed reinforced blast effect, or even create a hollow charge with improved performance (see high performance hollow charges obtained by coating them with reactive materials, such as for example coruscants (Korusaktiven)). For this purpose, the chromium hexacarbonyl which spontaneously decomposes spontaneously during its rapid reheating at temperatures above 200 ° C is particularly suitable. It can still be imagined that it is formed from the material of the cone shaped container, possibly in combination with spontaneously released metal with a fine distribution, a hollow charge dart or a projectile with improved performance compared to the container material. pure (higher density, higher hardness). For hollow fillers of this type, the metal carbonyls of other heavy metals, preferably molybdenum or tungsten are particularly suitable.

In the mode described above, one could also have hollow charges in which a layer of a thermal composition which liberally releases the relevant heavy metals is placed between the metal jacket and the explosive. With respect to such hollow fillers, the hollow fillers herein provided with metal carbonyl in the hollow charge coating container have the advantage that the release of the elemental heavy metal takes place more rapidly and with a comparatively finer distribution of so that one gets a hollow charge dart or a projectile of better quality.

The metal carbonyls to be integrated as hollow charge-coating containers in hollow charge explosives provided herein, depending on their chemical-physical characteristics, may be in the form of a compacted powder charge in a suitable container or solid body obtained by molding a powder charge in a suitable container (for example in the case of the use of chromium hexacarbonyl). Similarly, depending on the chemical-physical properties of the metal-carbonyl considered, the use of metal-carbonyl densifiable metal-carbonyl granules formed of a metal carbonyl and a suitable binder in amounts up to 10% maximum is not excluded. The containers in which the metal carbonyls are placed for the shaped hollow charge explosive charges described herein may be shaped into pointed cones or flat cones. Further, there is no restriction here on the form to be given to metal carbonyl-filled containers to achieve target-level effects. Among these are hollow charge liner containers which have areas with different wall thicknesses in order to increase their performance. In addition to copper as a material for the container, it is possible to use other suitable materials for making the containers. The portion of the metal carbonyl to be incorporated into the hollow charge coating container may be from 5% by weight to 95% by weight based on the total weight of the container and the integrated metal carbonyl. For explosive charges in the form of hollow charges proposed here, as far as explosive formulations are concerned, there is no restriction from the point of view of homogeneous explosives or explosive mixtures contained in them, any matrices of binders, or adjuvants such as stabilizers, catalysts or preparation auxiliaries. The explosive formulations to be used may contain additions of inorganic fuels and / or inorganic oxidizing agents in amounts up to 70% by weight, based on the explosive formulation itself.

Claims (15)

REVENDICATIONS1. Multi-envelope blast effect active material, characterized in that a metal carbonyl in the form of pure body, granules, mixture with an inorganic fuel or granules of a mixture with an inorganic fuel is integrated under the shape of a container (3) closed. 2. hollow charge or explosive charge (10, 1 (Y) shaped in hollow charge characterized in that a metal carbonyl in the form of pure body, granules, mixture with an inorganic fuel or granules of a mixture with an inorganic fuel is integrated therein in the form of a container (3) closed. 3. Active charge with a blast effect or hollow charge or explosive charge in a multi-envelope hollow charge according to any one of Claims 1 to 2, characterized in that the metal carbonyl contained therein is one of the compounds Cr (C0) 6, Mo (CO) 6, W (CO) 6, Fe (CO) 5, Fe2 (CO) 9, Fe3 (CO) 12, 4. Active charge with a blast effect or hollow charge or explosive charge shaped as a multi-shell hollow charge according to any one of Claims 1 to 3, characterized in that the metal-carbonyl (2, 4) integrated in a container (3 Closed as a pure body, depending on its physical and chemical properties, is in the form of a liquid. 5. Active charge with a blast effect or hollow charge or explosive charge in a multi-shell hollow charge according to any one of Claims 1 to 3, characterized in that the metal-carbonyl (2, 4) integrated in a container (3 ) closed, as a pure body, according to its chemical-physical properties, is in the form of an uncompressed or compressed powder charge or in the form of a solid developed in the container (3). 6. Active charge with a blast effect or hollow charge or explosive charge according to a multi-shell hollow charge according to any one of Claims J to 3, characterized in that the metal-carbonyl (2, 4) integrated in a container (3 ) closed is in the form of compressible granules composed of a metal carbonyl and a suitable binder in amounts up to 10% maximum by weight (referred to said mixture). Active charge with a blast effect or hollow charge or explosive charge in the form of a multi-envelope hollow charge according to any one of Claims 1 to 3, characterized in that the metal-carbonyl (2, 4) integrated in a container (3 closed is in the form of a mixture with an inorganic fuel (up to 50% by weight relative to the metal carbonyl), in the form of an uncompressed or compressed powder charge or in the form of an elaborate solid in the container. 8. Active charge with multi-jacketed blast effect or hollow charge or shaped explosive charge in hollow charge according to any one of claims 1 to 3, characterized in that the mixture of a metal carbonyl (2, 4) with a integrated inorganic fuel in a closed container (3) is in the form of compressible granules composed of a metal carbonyl (2, 4), an inorganic fuel and a suitable binder in amounts of up to 10% maximum in weight, referred to said mixture. 9. Active charge multi-hull blast effect or hollow charge or explosive charge shaped hollow charge according to any one of claims 1 to 3, characterized in that it comprises two or three envelopes, one or two envelopes, being formed from a squeezable, castable or mouldable formulation and the second or third shell comprises a metal carbonyl (2, 4) in a container (3) closed as a pure body, granules, mixture with an inorganic fuel or even in the form of granules of a mixture with an inorganic fuel. Active blast load according to one of Claims 1 and 3, characterized in that, in the case of a double envelope overall load structure, the envelope (1) consists of a compressible explosive formulation. castable or castable is used as a filler. 11. Active blast load according to claim 10, characterized in that it is arranged in a central core charge which is surrounded by a container filled with metal carbonyl (2, 4) in the form of a pure body, granules, mixing with an inorganic fuel, or even granules of a mixture with an inorganic fuel. 12. active charge with blast effect according to claim 10, characterized in that the container filled with metal carbonyl (2, 4) in the form of pure body, granules, mixture with an inorganic fuel, or even granules d a mixture with an inorganic fuel is wholly or partially surrounded by a compressible, flowable or meltable explosive formulation. Active blast load according to any one of claims 1 and 3 to 9, characterized in that in the case of an overall three-shell charge structure, the container (3) filled with metal carbonyl (2). 4) in the form of pure body, granules, mixture with an inorganic fuel, or even granules of a mixture with an inorganic fuel is arranged in a core-core or outer shell, the two remaining envelopes formed of a explosive formulation, compressible, castable or meltable being arranged accordingly. Active blast load according to claim 13, characterized in that the container (3) filled with metal carbonyl (2, 4) in the form of a pure body, granules, a mixture with an inorganic fuel, or even of granules of a mixture with an inorganic fuel is wholly or partially surrounded by envelopes formed of an explosive formulation, compressible, castable or mouldable, 15. Active blast load according to any one of claims 1 and 3 to 14, characterized in that the part by weight of the metal carbonyl (2, 4) in the form of pure body, granules, mixture with a inorganic fuel, or even granules of a mixture with an inorganic fuel relative to the overall load is between 10% by weight and 70% by weight, preferably between 15% by weight and 45% by weight. breath according to any one of claims 1, 3 to 12 and 15, characterized in that the part by weight of the explosive formulation, compressible, castable or meltable relative to the overall load, in the case of a structure with two envelopes, is between 30% by weight and 90% by weight, preferably between 55% by weight and 85% by weight. Active charge with a blast effect according to any one of Claims 1, 3 to 9 and 13 to 15, characterized in that the weight fraction of the explosive formulation, which can be compressed, castable or meltable, is based on the overall charge, in the case of a structure with three envelopes, in total is between 30% by weight and 90% by weight, preferably between 55% by weight and 85% by weight. Active blast load according to any one of claims 1 and 3 to 17, characterized in that the explosive formulations contained therein contain additions of inorganic fuel and / or inorganic oxidant in amounts up to 70% by weight, based on the explosive formulation concerned. Hollow charge or shaped charge according to any one of claims 2 to 8, characterized in that the charge-forming hollow container, filled with metal carbonyl in the form of pure body, granules, mixed with a fuel inorganic, or even granules of a mixture with an inorganic fuel, is shaped cone or frustoconical. Hollow charge or shaped charge according to any one of claims 2 to 8, characterized in that the charge-forming hollow container, filled with metal carbonyl in the form of pure body, granules, mixed with a fuel inorganic or even granular of a mixture with an inorganic fuel has a shape different from a cone or a truncated cone. 21. hollow charge or explosive charge shaped in hollow charge according to any one of claims 2 to 8 and 19 to 20, characterized in that the charge-forming container hollow, filled with 16. 17 ,. 18. 19. 20. Metal carbonyl in the form of pure body, granules, mixture with an inorganic fuel, or even granules of a mixture with an inorganic fuel has areas with different wall thicknesses. 22. hollow charge or explosive charge shaped in hollow charge according to any one of claims 2 to 8 and 19 to 21, characterized in that the proportion of metal carbonyl in the form of pure body, granules, mixing with an inorganic fuel or even granules of a blend with an inorganic fuel is from 5 wt.% to 95 wt.%, based on the overall weight of the hollow charge coating container and integrated metal carbonyl. A shaped hollow charge or explosive charge as claimed in any one of claims 2 to 8 and 19 to 22, characterized in that the hollow charge coating container is made of copper or other suitable material. Hollow charge or shaped explosive charge according to any one of Claims 2 to 8 and 19 to 23, characterized in that the explosive formulations contained therein contain additions of inorganic fuels and / or oxidizing agent inorganic in amounts up to 70% by weight, based on the relevant explosive formulation itself. Ammunition in the form of a munition released with or without a guide or ammunition-for guided weapon characterized in that it contains an active charge with a blast effect or a hollow charge or an explosive charge shaped as a multiple enveloped hollow charge according to Claims 1 to 24. Ammunition in the form of a guided or unguided missile or tube weapon ammunition, characterized in that it contains an active blast load or a hollow charge or an explosive charge characterized in that a multiple-shell hollow charge according to claims 1 to 24. Ammunition in the form of a mortar shell or a rocket, characterized in that it contains an active charge effect of 23. 24. 25. 26. 27, 5, 10, 10 or a hollow charge or an explosive charge shaped as a multiple-shell hollow charge according to claims 1 to 24. 28. Ammunition in the form of a shoulder-arm charge, characterized by the it contains an active charge with a blast effect or a hollow charge or an explosive charge shaped as a multi-shell hollow charge according to claims I to 24. 29 Ammunition characterized by the fact that blast active charges or Hollow charges or explosive charges shaped as a multiple shell hollow charge according to claims 1 to 24 are incorporated as submunitions or partial loads. 30. Munitions of modular design characterized in that they, by adaptation of closed containers filled with meta-carbonyl in the form of pure body, granules, mixture with an inorganic fuel, or even granules of a mixture with a inorganic fuel form an ammunition according to claims 25 to 29.