DE2822699C1 - Fire splinter body with a fire splinter charge - Google Patents

Description

The invention relates to a fire splinter body with a fire fragment charge consisting of one with a bottom and cover provided casing steel and one in the casing tube concentric internal steel separator, where at in one through the casing tube and the inner separation tube formed fire splinter charge chamber a fire splinter charge and in a blast formed by the inner separation tube an explosive charge is arranged, both Chambers are locked against each other and at the blasting material chamber at least one ignition mechanism for the delayed Ignition of the explosive charge located therein is provided.

Fire fragment bodies with a fire fragment charge are already known. They generally consist of one Steel case in which there is a fire fragmentation charge as fire splinters with iron or steel body, along with an explosive charge located. The fire mass is either one by igniting the explosive charge at the same time ignitable mass or a mass that is only at Hitting the target is lit by friction, for example, a mass made from a pyrophoric mate rial. By igniting the explosive charge in the fire splinter charge located in the steel housing under high acceleration and with lighting of the in or the fire mass contained in the fragmentary charge to the brought each goal. All objects come as a target te questioned by the accelerated burning Splinters can be made inoperable. For this include, for example, aircraft fuel tanks, Motor vehicles or fuel depots, the content of which Punching through the respective containers set on fire becomes.  

DE-AS 11 72 157 describes a splinter floor with a hollow inner container and with one on top of it brought shell from preformed individual explosive pieces, which are glued and between the inner container and one outer wrapping, which is characterized by that the explosives consist of metallic bodies, those with a pyrogenic substance, preferably a metal or an alloy coated, the pyrogenic Characteristics when hitting the target to impact kung come, and that the explosives so covered are embedded in a synthetic resin mass. That about pull the metallic body needed pyrogenic metal is preferably from the group aluminum, magne sium, zircon, titanium or the pyro selected alloys. The explosives can be made Steel or other material.

DE-AS 17 03 840 is an explosive projectile with at least from a secondary storey that is attached to an explosive body is arranged and that an open blind hole points in a fire charge by another charge is covered, which is characterized in that the Mouth of the blind hole is turned away from the explosive device, and that the further charge from a low-gas glow charge that exists after a burn time, when it hits bridged the time of high detonation pressure, the fire charge ignited. The glow charge is preferred wise from manganese and lead chromate with a burning time of 0.2 seconds. In a preferred embodiment, the Axis of the secondary floor compared to a cross section level of the explosive bullet inclined at an angle of 60 °.

The known devices now fulfill their function however, not entirely satisfactory. This is first and foremost attributable to the fact that their fire fragments ent neither is made of a metal that the respective goals does not penetrate to the desired extent, or a fire  contains mass that can only be ignited to a limited extent or whose fire goes out so quickly that the Effect of the fire splinter charge heavily influenced in the target is pregnant. The mass (and acceleration) of each fire splinter is for the breakthrough performance (kinetic energy) responsible, while those at the Fire splinters existing fire mass the required Fire effect (thermal energy) should result. Now the fire mass of such known fire splinters at usual disassembly of the ver with a fire fragment charge seen fire fragment body from the explosive charge lit, then the fire effect of such fragments equals zero. The same also applies if the fire mass the splinter is lit, but ver too quickly burns. The splinter only reaches its destination when he no longer has the absolutely necessary fire kung. The well-known fire splinters also have also the disadvantage that their filling with fire mass upon detonation of the explosive charge from the fragments can be solved, so that for such splinters at the destination there is also no fire effect at all. The fire fragment charge of the known fire fragment bodies therefore has the overall disadvantage that for them a reliable mode of operation required combination is not given from kinetic and thermal energy. Finally, all such fire splinter bodies are in their construction is relatively complex, and this applies above all to the special fire required fragmentation charge.

The object of the invention is therefore to create a Fire splinter body, for which practically everything Splinter material for a sufficiently effective fire required combination of kinetic and splitter thermal energy, namely breakdown power and fire effect, is given.  

This task is the fire splitter mentioned at the beginning body according to the invention now solved in that

• a) the fire splinter charge ( 3 ) consists of high-melting metal splinters ( 23 ) which are embedded in a metallothermal heating element ( 25 ), which with at least one ignition mechanism ( 27 ) from the metallothermal heating element ( 25 ) immersed electrically or mechanically ignitable ignition tube ( 35 ) is seen,
• b) the inner separation tube ( 11 ) with an insulation ( 29 ) which protects against excessive heat transfer is seen so that there is no premature ignition of the explosive charge ( 19 ) in the explosive chamber ( 17 ), and
• c) the firing mechanism (21) fuel charge for the delayed ignition of the explosive present in the explosive chamber (17) (19) of at least one Ver associated with the located in the incendiary fragmentation charge chamber (13) metallo thermal heating composition (25) deceleration piece (37) with a detonator ( 39 ) be, which is arranged away from the ignition mechanism ( 27 ) for the me tallothermal heating unit ( 25 ) that it is initiated by the heating unit ( 25 ) only after this has completely reacted.

The metal splinters preferably consist of a high melting metal that has a melting point of over 1600 ° C, especially from broken chrome, and they have preferably a particle weight of 5 to 30 g.

The metallothermal heating set is preferably a heater sentence that during its reaction in the fire splinter cargo chamber no premature fire destruction  splintered charge chamber causing excessive pressure hung results with a sufficient glowing of the Metal splinters of sufficient burn rate and Reaction temperature burns off during and after his reaction to the original location and arrangement the metal splinter doesn't change much has a solid structure. Metallothermal heating sentence generally contains zircon as the reducing metal, Titanium, silicon, aluminum or alloys of these me talle with each other or with other metals, and as Oxygen carrier metal oxides and / or oxygen-containing Metal salts. Iron (III) oxide is used as an oxygen carrier, Titanium dioxide and / or barium sulfate are preferred. One used A stable, metallothermal heating set is made of aluminum, Iron (III) oxide and titanium dioxide, preferably in quantities from about 25 to 35% by weight aluminum, 25 to 40% by weight Iron (III) oxide and 30 to 55 wt .-% titanium dioxide. The Ge is titanium dioxide in the metallothermal heating unit generally the higher the smaller the mean grain size of aluminum is. The amount by weight of metallo thermal heating set generally corresponds approximately to that Weight amount of metal splinters. The composition and the amount by weight of the metallothermal heating unit definitely designed to respond during the reaction there is sufficient glowing of the metal splinters. The heating set should also be conveniently so create that during or after his reaction the original location and arrangement of the metal splinters not substantially changing largely solid structure is preserved, and this means that the accruing Embers should be solid to viscous so that the metal fragments remain embedded in it. In the reaction of the metallothermal heating set is therefore best a required, very hot sinter body are formed, through which the to be heated Metal splinters within a few seconds, for example  a period of 5 to 30 seconds, at least heat to red heat and ideally to white heat. An optimal function results when the metal lothermal heating element and the metal splinters with each other are pressed into an active body.

The basics of finding and selecting a he metallothermal heating unit which can be used according to the invention can be found, for example, in Ullmann's encyclopedia of tech African chemistry, 3rd volume (1953), pages 428 to 436. The heating sets to be used here are therefore on known. It is therefore only one certain selection of heating kits that set out the above ten and in the present case essential properties well fulfilled.

It must be avoided that the inventive Fire splinter body for the construction of the individual parts materials used by the in the reaction of the Metallothermal heating set occurring heat development become inoperable before you can do this through the deliberate disassembly of the entire fire splinter body ha would like to. This is generally done using Steel achieved as a building material. Furthermore is imperative make sure that it is at least until completion the reaction of the metallothermal heating unit to none for premature ignition of the in the explosives chamber sufficient heat over the explosive load transfer from the incineration charge chamber to the explosives cloth chamber is coming. For this purpose, the inner separation tube by arranging for an excessive heat transfer protective insulation designed to be heat-insulating, this insulation preferably inside the interior separating tube is arranged. The insulation is there heat from an inner insulation tube insulating material, for example ceramic masses,  Ceramic paper or foam concrete, where appropriate as Deposits of aluminum foils are present. More appropriate is between the inner separation tube and the insulation arranged an additional insulation layer inside the tube, made of the same materials as above or can consist of other materials. The one in the blasting Explosive charge located in the material chamber must therefore be ge compared to that existing in the incineration charge chamber metallothermal heating set overall so heat insulating be assured that the me heat occurring in the tallothermal heating unit one for early ignition of the explosive charge transfers sufficient dimensions to the explosives chamber. So there must be a deflagration in the explosives chamber existing explosives can be avoided.

The explosives in the explosives chamber manure is best made from a high explosive Deflagration temperature and detonation speed. Trinitrotoluene, nitropenta, hexogen or oxogen preferred as an explosive.

The ignition mechanism for the metallothermal heating set consists of those immersed in the metallothermal heating set Ignition tubes that can be ignited electrically or mechanically.

The ignition mechanism for delayed ignition in the Explosive chamber located explosive charge exists from at least one with that in the incineration charge chamber located metallothermal heating set in Ver bonded delay piece with a detonator, the ignition mechanism for the metallothermal The heating element is arranged so that it is only after full constant reaction of the heating set initiated by this becomes. This can be achieved by using the ignition mechanism for the explosive charge in the bottom part or in the head part the explosive chamber is attached during ignition  Mechanism for the metallothermal heating set in the lid or is arranged in the bottom of the casing tube. Another Suitable option for this is that the Zünd mechanism for the explosive charge in the base part and in the head part of the explosives chamber and the ignition mechanism for the heating set in the middle area of the casing pipe is ordered. Furthermore, the Zünd can be used for this purpose Mechanism for the explosive charge also in the middle part arrange the explosive chamber and the ignition mechanism for the heating set in the floor and in the cover of the casing pipe provide. The bottom part and / or the head part of the The best way to do this is to use an explosive chamber on the bottom and / or the lid of the man rest on the tube. This way it can be in the ground zen part and / or in the head part of the explosive chamber tral arrange a delay piece with a detonator nen. The one under the bottom part or over the cover part lying space of the casing tube is completely with the Metallothermal heating set filled, so that in the Explosive chamber located explosive charge first after complete reaction of the metallothermal heating set delayed via the intended ignition mechanism is ignited.

At the explosives chamber either one or also several ignition mechanisms for delayed ignition of the explosive charge contained therein, and The same applies to the ignition mechanism with which the Heating set is lit. The only thing that is essential is that is ensured that the ignition mechanism for those in the Explosive chamber located explosive charge only be is done when the metal splinters by reaction of the metallothermal heating set to the required tem temperature are heated. This is easiest to do by achieving that the ignition mechanism for the in explosive charge located in the explosive chamber arranges a place where the in the fire splitter  charge chamber located last reacted, see above that this ignition mechanism only after complete through reaction of the heating unit is thermally activated becomes.

Bottom and cover of the casing tube are with the casing tube best connected by welding. Because the blasting load of fabric in the manufacture of the fire splinter body are of course only introduced at the very end can, the cover of the casing tube is expedient designed so that it is at least an introduction sufficient explosive hole in the explosive charge points, which are closed with a bayonet lock cover can be. Select to avoid heat transfer welding the cover to the casing tube on the be sensitive heating kit must at least in the area of sweat seam between the facing the cover of the casing tube Part of the heating set and the cover of the casing tube one Thermal insulation layer may be arranged.

The invention is explained in more detail with reference to the drawing. Show in it:

Fig. 1 is a vertical section through a guide die off for an inventive incendiary fragmentation body, in which the net is Anzündme angeord mechanism for the heating composition in the lid, while the firing mechanism is for the explosive charge in the bottom part of the explosives chamber,

Fig. 2 shows a vertical section through a further embodiment for a fire splinter body according to the invention, in which the Ananme mechanism for the heating unit is arranged in the lid and in the bottom of the jacket tube, while the ignition mechanism for the explosive charge is located in the middle part of the explosive chamber.

Is described in detail from Fig. 1, an incendiary fragmentation body 1 having a fire fragmentation charge 3 shown, the housing is composed of a bottomed 5 and cover 7 provided jacket tube 9 made of steel, in the interior of virtually concentrated symmetrical to the jacket pipe 9, an inner separation pipe 11 is also disposed steel . In a through casing 9 and the inner separation pipe 11 formed Brandsplitterla-making chamber 13 is an incendiary fragmentation charge 15 arranged, while in a recess formed by the inner cutting tube 11 snap fuel chamber 17 is an explosive charge is present nineteenth Both chambers 13 , 17 are closed against each other. Bottom 5 and cover 7 of the housing are connected to the jacket tube 9 by welds 45 . The casing tube 9 with the bottom 5 and the inner separating tube 11 are made of steel with a material thickness of about 2 mm. The cover 7 of the casing tube 9 is also made of steel, but has a material thickness of approximately 4 mm. The bottom part 41 of the explosives chamber 17 has spacers 43 which rest on the bottom 5 of the casing tube 9 . In the bottom part 41 of the explosive chamber 17 , a Zündmecha mechanism 21 is arranged from a delay piece 37 and an explosive capsule 39 through which the explosive charge 19 located in the explosive chamber 17 detonates who can. The inner separating pipe 11 is designed to protect the insulation 29 from heat insulation from an excessive heat transfer from the fire splitting chamber 13 to the explosive chamber 17 . This Iso lation 29 is net angeord inside the inner separation tube 11 . It consists of an inner pipe insulation 31 of a ceramic laminated with aluminum paper and a separator between the inner tube 11 and the insulating pipe 31 located senses additional insulation layer 33, it is in the paper to a laminated with aluminum ceramic. The explosive charge 19 consists of tri-nitrotoluene, nitropenta, hexogen or oxogen as an explosive.

In the fire splinter charge chamber 13 , a fire split charge 15 made of broken chrome 23 is arranged, which is embedded in a metallothermal heating set 25 . This heating set 25 consists of aluminum, iron (III) oxide and titanium dioxide, for example a mixture of 28.6% by weight aluminum powder with a grain size of 125μ, 30.0% by weight iron (III) oxide and 41.4 % By weight of titanium dioxide. Instead of this, for example, a mixture of 29.2% by weight aluminum powder with a grain size of 65μ, 22.5% by weight iron (III) oxide and 48.3% by weight titanium dioxide can also be used. Mixtures of 50 to 70% by weight, preferably 60% by weight, barium sulfate, 15 to 25% by weight, preferably 20% by weight, aluminum powder and 15 to 25% by weight are also suitable as heating sets. , preferably 20% by weight, copper powder as reaction-regulating agent, or mixtures of 75 to 85% by weight, preferably 80% by weight, barium sulfate and 15 to 25% by weight, preferably 20% by weight , Aluminum powder. The heating element 25 is electrically ignited via an ignition mechanism 27 arranged in the cover 7 of the casing tube 9 , and this is, for example, a lighting tube 35 immersed in the metallothermal heating element 25 . The ignition set located in the ignition tube 35 consists, for example, of a mixture of magnesium powder and iron (III) oxide, which advantageously contains 31.4% by weight of magnesium powder and 68.6% by weight of iron (III) oxide. The fire splinter charge 3 from the chrome splinters 23 , which are embedded in the heating element 25 , represents an active body produced by pressing, which is expediently formed by layer-wise pressing.

In the area of the weld 45 between the cover 7 of the casing tube 9 facing part of the heating element 25 and the cover 7 of the casing tube 9 , a heat insulating layer 51 is arranged, which is ceramic paper and aluminum foil. This heat insulating layer 51 primarily has the purpose of protecting the heating element 25 when the cover 7 is finally welded onto the jacket tube 9 from excessive heat transfer.

In the cover 7 of the casing tube 9 there is also a central bore 47 , in which a bayonet lock cover 49 is seated. Through this central bore 47 , the explosive charge 19 is introduced into the explosive chamber 17 as a closing measure in the manufacture of the present fire splinter body 1 , the whole being then closed with the bayonet closure cover 49 . On the bayonet cap 49 facing surface of the explosive charge 19 located in the explosive chamber 17 there is a shim 53 made of ceramic paper before, through which the respective volume of the explosive charge is balanced.

With 55 the head part of the explosive chamber 17 is designated net, while with 57 the central region of the casing tube 9 and with 59 the central part of the explosive chamber 17 are given.

The further embodiment of a device according to the invention shown in FIG. 2 is identified by the same reference numerals as in FIG. 1, so that there is no need for additional discussion thereof.

According to the above statements is for the functionality of the fire splinter body according to the invention is only essential, that you have a combination of a fire fragment charge from metal splinters in a suitable heating set and out an explosive charge in such a device  orders that an ignition of the metallothermal heating set with sufficient heating of the metal splinters is enabled before the entire device by Zün their explosive charge is dismantled so that the high heated metal splinter reach the respective target can. The present device can therefore take the form of projectiles, missiles, bombs, grenades or other Have throwing bodies. Just the preferred use of It is attributable to chrome splinters that it can be Fragmentation has to do with a material that after the necessary heating to red heat to white heat has such mechanical properties that the highly heated chrome splinters when hitting the jewei target over what is necessary to penetrate it Hardness and strength. The integrity of the chrome splinter is essentially retained.

As target objects for the existing fire splinter bodies all objects come into question by the impact of the highly heated metal splinters set on fire and thereby can be made inoperable, such as Aircraft or motor vehicles with fuel tanks or Fuel storage. That by detonating the explosive charge and tearing open the entire fire body at high speed th and highly heated metal fragments penetrate the respective fuel tank and put the be in it sensitive and / or leaking fuel then due their high temperature on fire.

Claims (7)

1. Fire splinter body with a fire splinter charge, consisting of a steel jacket with a bottom and a cover and a steel inner pipe concentric in the jacket pipe, with a fire splinter charge and a fire formed by the inner pipe in a fire splinter charge chamber formed by the jacket pipe and the inner pipe Explosive chamber is arranged an explosive charge, both chambers are closed against each other and on the explosive chamber at least one ignition mechanism for delayed ignition of the explosive charge located therein is seen before, characterized in that

• a) the fire splinter charge ( 3 ) consists of high-melting metal splinters ( 23 ) which are embedded in a metallothermal heating element ( 25 ), which with at least one ignition mechanism ( 27 ) from the metallothermal heating element ( 25 ) immersed electrically or mechanically ignitable ignition tube ( 35 ) is seen,
• b) the inner separation tube ( 11 ) with an insulation ( 29 ) which protects against excessive heat transfer is seen so that there is no premature ignition of the explosive charge ( 19 ) in the explosive chamber ( 17 ), and
• c) the firing mechanism (21) fuel charge for the delayed ignition of the explosive present in the explosive chamber (17) (19) of at least one Ver associated with the located in the incendiary fragmentation charge chamber (13) metallo thermal heating composition (25) deceleration piece (37) with a detonator ( 39 ) be, which is arranged away from the ignition mechanism ( 27 ) for the me tallothermal heating unit ( 25 ) that it is initiated by the heating unit ( 25 ) only after this has completely reacted.

2. Fire splinter body according to claim 1, characterized in that the metal splinters ( 23 ) are made of broken chrome with an average particle weight of 5 to 30 g. 3. Fire splinter body according to claim 1, characterized in that the metallothermal heating element ( 25 ) as a reducing metal zirconium, titanium, silicon, aluminum or alloys of these metals with one another or with other metals and as an oxygen carrier contains metal oxides and / or oxygen-containing metal salts. 4. fire splinter body according to claim 3, characterized in that the metallothermal heating element ( 25 ) from about 25 to 35 wt .-% aluminum, 25 to 40 wt .-% iron (III) oxide and 30 to 55 wt .-% titanium dioxide consists. 5. fire splinter body according to claim 1, characterized in that the metallothermal heating element ( 25 ) and the metal splitter ( 23 ) are pressed together to form an active body. 6. fire splinter body according to claim 1, characterized in that the explosive charge in the explosive chamber ( 17 ) be sensitive ( 19 ) consists of an explosive with high deflagration temperature and Detonationsgeschwin speed. 7. fire splinter body according to claim 1, characterized in that the ignition mechanism ( 21 ) for the explosive charge ( 19 ) in the bottom part ( 41 ) or in the head part ( 55 ) of the explosive chamber ( 17 ) and the ignition mechanism ( 27 ) for the metallothermic Heating set ( 25 ) is arranged opposite each other in the cover ( 7 ) or in the bottom ( 5 ) of the casing tube ( 9 ).