DE2036726A1 - Improved effect of the pressure surge from explosive devices - Google Patents

Description

PATENT ADVOCATE DR. HANS-GUNTHER EGGERT ₁ DIPLOMA CHEMIST

5 XDIN-LINDEKTHAL 7ETER-KINTGSN-STaASSE 2 2036726

Cologne, June 16, 197 © Rö / pz / llo

Dynamit Nobel AG, Troisdo'rf Improved effect of the pressure surge from explosive devices

The invention relates to a method for improving the Effect of the pressure shock from explosive devices, which with the help of a gas flow of high speed and high energy density in predetermined cavities or gaps in the explosive device or with the help of an ignition chain made of exploding wires.

It is known that brief pressure surges of high energy are caused by a massing of explosives, e.g. in so-called "Concentrated charges" have meaning for the destruction of objects. The object to be destroyed is all the sooner smashed, the higher the pressure surge.

It is also known that in pierced explosive devices, gas flows during detonation in the bores high speed and high energy content can occur. The speed of the Gas flow considerably greater than the detonation speed the ability of the explosives to be used. With a division of the hole through partition walls. e.g. from explosives or inert material, in individual chambers of a certain length ignitions occur in front of the detonation front

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According to the German patent application P 16 46 248.2 is a Detonation of explosive devices by detonating chains made of exploding wires possible .. ■

It has now surprisingly been found that you can get a considerable Increase in the pressure surge outside a explosive device obtained if you put them in bores and / or crevices developing gas flow of high speed and energy density for "pre-ignition" and thus for accelerated Implementation of the explosives of such bodies exploiting, or if one of the above-mentioned detonation chain from exploding Wires used.

The effect of the pressure surge of an explosive charge on the environment depends first of all on the size of the detonation pressure at the phase boundary between the explosive and the surrounding medium. The detonation speed and thus the detonation pressure are different in the explosive from the chemical one Structure and density of the explosive depend on and not on whether an explosive device is detonated at several points in short time intervals.

When using an explosive column with an axial bore, this being divided into chambers of a certain length by partitions made of explosives, it becomes a considerable one Obtain enlargement of the pressure surge outside the column. It can be seen from Example 5 that the same effect is also achieved by using the ignition chain made of exploding wires. The inventive idea of a pressure surge enlargement can be transferred to almost any form of explosive device, to "pre-ignitions" and thus a to achieve accelerated implementation.

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The gas flow of high speed and energy density required for this can be any ■ Cross-section (e.g. circle, ellipse, square, rectangle, star or parts of these geometric figures) will. However, the cross-sections can also be asymmetrical be or have an irregular border. The cross-sections can vary over the length or depth of the Cavities or crevices continuous or discontinuous j lent change. For reasons of convenience, a "

Explosive devices, possibly also with several parallel ones or anti-parallel cavities and / or gaps of equal or unequal cross-section and length have been provided.

If an explosives column consists of two nested one into the other Columns, one of which is solid and the other is hollow and there is an annular one between the two columns Air gap, one also obtains one increased effect of the pressure surge outside the explosive device. The increase in the pressure surge is not limited only on the use of annular gaps in the longitudinal direction of explosive devices to form a gas |

flow of high speed and energy. Such ' With certain explosives, currents form in any type and shape of appropriately dimensioned gaps. Such an explosive column can also consist of several columns placed one inside the other with corresponding spaces exist.

The partition walls dividing the cavities and / or gaps into chambers of certain lengths can be made from the explosive the explosive device or from another explosive or from an inert material (e.g. metal, plastic, Ceramic), the thickness of the partition walls can be

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can be varied over a wide range. You have to Chamber lengths and the dimensions of the explosive device adapted The ignition chains consist of alternating pieces of thick and thin wire of the same or different types Length. When the chain is ignited, the thin pieces of wire undergo an explosive transformation. The surrounding Explosives are detonated. The above-mentioned structure of the chain results in an equilateral and uniform initiation of the explosives or the detonator is guaranteed over the entire length ^ e ** chain. The ignition can be linear, ring-shaped or flat or in a spatial arrangement.

Even with explosive devices with a central ignition, the Implementation through the gas flow in predetermined cavities and / or crevices or through the ignition chain from exploding Wires are accelerated.

So can 2.B. in the case of a bullet made of explosives of their center point, i.e. the ignition point, in radial Direction in geometrical or any distribution drill holes in a smaller or larger number that go through Partition walls are divided into chambers of the required length. Kit the appropriate arrangements can have the effect the pressure surge can also be significantly improved with these explosive devices.

An increase in the pressure surge is also obtained with explosive lenses similar to optical lenses and with Explosive articles of a certain shape for the generation of directed shock waves by introducing them into chambers Cavities and / or crevices or through use

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the ignition chain made of exploding wires. (These bodies are produced, for example, by sintering in accordance with German patent specification P 16 46 28JJ.2).

In the case of explosive devices, it is generally possible to introduce cavities and / or gaps divided into chambers or through the use of the ignition chain made of exploding wires in malicious arrangements and directions of the pressure surge in terms of its spatial distribution influence.

In Figs. 1 to 4 are some embodiments for a Explosive device with improved effect of its pressure surge shown.

In Fig. 1, a cylindrical explosive body 1 is Darge «represents, which has a Eohrung J> which is divided into individual chambers by partition walls k, which can consist of explosives or an inert material. The explosive device is caused to detonate by means of an m Initialzündsatzes. 5 ".

FIG. 2 shows an explosive device which consists of individual cylindrical bodies 2 which are separated from one another by gaps 7. A central bore J runs through the entire explosive device. Here, too, the gaps 7 or the bore 3 can be divided into individual chambers. Arrangements with cabbage spaces and / or crevices and / or with an ignition chain made of exploding wires can be introduced into the explosive devices in a simple manner. In Fig. 2 a further arrangement is shown in which the ignition rod Io is inserted into a central Eohr 3,

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wherein the ignition rod Io consists of an inserted ignition chain 6 owns exploding wires. The ignition rod Io can also an envelope 11, e.g. sheet metal / cardboard or Plastic, which are used to protect the ignition rod, for example for storing the ignition rod or in the event of incompatibility the explosives of the detonating rod and the explosive device 1 is attached. Here, the explosive device 1 is also spared again with gaps and / or cavities.

“In Pig. K is shown an explosive, the explosive consists of a cylindrical body 8, around which a further hollow cylindrical explosive body 9 is arranged so that between the two a gap 7 remains.

The invention is explained in more detail below with the aid of examples. As an indicator of the effect of the pressure surge pressure cells with lead membranes were used. From the The bulging of the membranes caused by the pressure surges allows conclusions to be drawn about the size of the impact draw.

There were cylindrical columns of explosives 1 without a cladding used to avoid being blasted through the fragments of the Enclosure to damage the pressure cells and their membranes.

There were pillars of explosives with small and large amounts of explosives selected.

In the first five examples, the explosive columns 1 were each made up of 6 cylindrical single-core bodies 2 with Io mm

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Bore 2 made of sintered INT (density: 1.2 g / cnr, detonation speed: 52oo m / s) with jo now outside diameter and 66 mm long combined to a total length of approx. 400 mm. (Sintered explosives can be used according to the German patent application P 16 46 28 ^ .2 produced will). The weight of the explosives was about 42o g.

The explosive column 1 was horizontally at a height J

of looo cm above the. Floor-mounted and one side of 'tung by a detonator no. 8 (an aluminum capsule with squib, a primary Sass of o, J> g BleiJbrizinat and a secondary set of o, 8 g tetryl) with the interposition of a Nitropentapressiings 5 ignited. Two pressure cells with lead membranes 2 mm thick stood on the floor at a distance of 25o mm above the putty of the explosive column.

The specified depths of curvature of the lead membranes in the pressure cells were measured using the same test set-ups with modification of the test conditions listed in the individual examples. \

example 1

Explosives column with through hole 2 without subdivision in chambers:

Membrane 1, arch depth 11.1 mm
¹¹ 2, "11.2 mm

Example 2

Explosives column with through hole 2 without subdivision into chambers, hole with an inert material (Hard PVC) filled in:

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Membrane 1, arch depth 11.2 mm "2," 11.3 now

Example 3

Explosives column with subdivision of the bore ^ into 4 chambers 8o mm long by dividing walls 4 of 18 mm thick Explosive:

Membrane 1, camber depth 14.7 nanometers, ¹¹ 2 "14.8 nanometers.

AtSDiel 4

Explosives column with subdivision of the hole jj into 5 chambers of 6o ran "^ length through partition walls 4 of 18 mm thickness made of explosives.

Membrane 1, V / oil depth 14.2 ram " 2," 1 ^, 9 nsm.

In the next example, the axial hole J> of the explosive column. 1 filled in with explosives. The column was ignited once by a detonator aluminum No. and the other quay by an inserted ignition chain β made of exploding wires.

Example 5 ''

a) Ignition by a detonator Alu Wr · Membrane 1, depth of curvature 1Γ, 8 mm ¹¹ 2, "12.1 mm

b) Ignition by ignition chain made of exploding wires? Membrane 1, honeycomb depth 15.3 now. _ ¹¹ 2, ⁿ 15.6 mm.

In Examples 6-9, explosive columns with Io mm-

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Bores 3 without sheaths of about 1 m length, each composed of 7 cylindrical bodies 2 measuring so mm in diameter and 150 mm in length, shot in a horizontal position 2ooo mm above the ground. The columns consisted of sintered bodies of the explosive TNT (density 1.2 g / cm2 detonation speed 500 m / s) and of TNT + microballs (mixing ratio ΤίίΤ / microballs 96/4. Density 0.95 g / cm ^ - detonation speed 45oo m / s. j (See German patent application P 16 46 283.2) On the floor, across the center of the explosive columns, pressure cells with lead membranes were placed symmetrically about the center line of the column at a distance of 2 m Interposition of a nitropenta squeeze detonated by a detonator aluminum No. 8 were shot into chambers with and without subdivision '\ ' of the axial bore.

Example 6 _; . ^:

Explosives column made of sintered TNT with continuous drilling I tion 3 without subdivision into chambers, weight of the explosive approx. βοοο g;

Membrane 1, V / recess depth 14.8 mm '.

¹¹ 2, "15, o mm.

Example 7 . ^:

Explosives column made of sintered TNT with subdivision of the hole JJ in 10 chambers of 80 mm length through partition walls 4 of 18 mm thickness made of explosives, weight of. Explosives approx.
Membrane 1, arch depth 18.9 mm,
"2," 18, β mm.

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Example 8

Explosives column made of sintered TNT + microballs with a through hole 3 in Io chambers of 80 mm length through partition walls 4 of 18 mm thickness made of explosives, weight of the explosives approx. 48oo g:
Membrane 1, arch depth 18.4 mm,
"2," 18.3 mm »

A significant improvement in the effect of the pressure surge through an accelerated conversion of the explosive device, caused by a gas flow of high speed and energy and / or through an ignition chain of exploding wires, is clearly visible in the examples. The compressive curvature of the lead membrane caused by such a dynamic impact, however, is no longer proportional to the stress with increasing curvature depth. it is between ^ o and 4o # ·.

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Claims (9)

Claims rl) method for improving the pressure surge of explosive devices, characterized in that the cracks to ffuir.se tzung in cavities and / or gaps (3, 7) Occurring gas flow of high speed on the envelope and / or on explosives / is directed and / or | Detonation chains made of exploding wires are housed in the explosive device. 2. The method according to claim 1, characterized in that / 3 in the cavities and / or gaps (3, 7) are attached at intervals stowage points for the gas flow. 3. The method according to claim 1 or 2, characterized in that the explosive device is provided with at least one axial bore (3) which has storage locations (4) lying one behind the other. 4. The method according to any one of claims 1 to 3, characterized in that " indicates that the explosive device is made in a row arranged individual bodies (2). 5. The method according to any one of claims 1 to 4, characterized in that the explosive device with an ignition rod is provided, which has a through hole with storage sites one behind the other. 6. Explosive device with improved effect of the pressure surge,. characterized by cavities and / or gaps (3, 1) and / or ignition chains made of exploding wires. 109885/0177 bad original * 7. explosive device according to claim 6, characterized by in the cavities and / or gaps (2, 7) attached storage sites 8. explosive device according to claim 6 or ¹ J, characterized by at least one bore (2) wit one behind the other storage sites (4). 9. explosive device according to claim 6 to 8, characterized by individual bodies (2) arranged one behind the other. BATH ORIGINAL 10 9 8 85/0177