DE1170297B - Mixed explosives - Google Patents

Description

Mixed explosive The invention relates to a mixed explosive from ammonium nitrate, trinitrotoluene as the explosive component and water.

It is known to use ammonium nitrate with an explosive component and water to combine into mixed explosives. This is how the German Auslegeschrift 1009 describes 990 a plastic safety explosive made from 10 to 70% ammonium nitrate, 20 to 45% explosive component and 3 to. 25% water and British patent 597 761 similar explosive compositions with 64 to 73% highly explosive components.

The invention has the task of mixed explosives of this kind, the highest possible working capacity with the best possible ignition sensitivity to combine and at the same time to achieve the greatest possible profitability. It solves this task through the special selection of the explosive components Type, quantity and grain size.

A mixed explosive according to the invention is characterized in that that it is trinitrotoluene in an amount of about 15 to 65% as the explosive component, Contains water in an amount of about 5 to 20% and the remainder ammonium nitrate, wherein the trinitrotoluene is in coarse grain form with a particle size greater than 0.5 mm or in flaky form. Preferably the TNT is of one particle size from about 1.2 to 1.7 mm in front.

It is an essential characteristic of the mixed explosive according to the invention, that the TNT forming the explosive component has a grain size of more than 0.5 mm. If you consider the sensitivity of the mixed explosive to ignite above the grain size of the TNT, a curve is obtained which suddenly appears at a grain size of about 0.5 mm increases, has a turning point at a grain size of approximately 0.8 mm and at about 1.2 to 1.7 mm, the preferred grain size, approaches the horizontal. This The course of the curve requires that with the same ignition sensitivity and otherwise the same composition a mixed explosive only needs to contain half to a third as much TNT than one with normal TNT, which has a grain size smaller than 0.5 mm. For example one can determine the ammonium nitrate / TNT ratio for charges 13 cm in diameter that with an impact charge of 160 g of an explosive from equal parts TNT and Pentaerythritol granitrate (PETN) can be detonated, at most up to 1.5, corresponding to at least 35% TNT in the finished sludge. at For coarse TNT, on the other hand, an ammonium nitrate-TNT ratio of 4.0 is possible, correspondingly only about 15% TNT in the finished sludge. The use of TNT in the normal fine-grained form, d. H. with a particle size of less than 0.5 mm should also should therefore be avoided because the fine-grained particles are already in the dry state detonated in a diameter of 0.6 cm with normal detonators can. Another disadvantage of fine grain TNT is that it is because of its relative poor wettability cannot be easily slurried with water. Further the sludge of fine TNT and water has a critical diameter of 15 cm and requires a very large detonator.

The trinitrotoluene can also be used in flaky form. The flaky TNT has practically the same ignition sensitivity as the coarse-grained one However, TNT, when used in the form of a slurry according to the invention, shows the disadvantage of being much more sensitive when dry and less To have density as well as to result in a more difficult to handle sludge. Of the The term trinitrotoluene used here and in the following is not only intended to be pure TNT include, but also the "pourable" mixtures with ammonium nitrate, sodium nitrate etc., that is, the industrial products known to those skilled in the art as "tols". These mixes are preferably used in the form of trickle tower products. The ammonium nitrate can be fine, coarse or an intimate mixture of fine and coarse material. That fine material should preferably have a grain size of about 0.3 to 0.1 mm and below that, and the coarse material should be between a grain size of approximately 0.5 and 1.7 mm. It is economically beneficial to have one among each Conditions as large a proportion of the TNT as possible due to the cheap ammonium nitrate substitute. A mixed ammonium nitrate is particularly beneficial for this purpose, because it allows to reduce the water content and thus the maximum replacement of TNT made possible by ammonium nitrate.

The ignition sensitivity reaches a maximum at an ammonium nitrate / TNT ratio of about 3: 2 and becomes too low for practical purposes at an ammonium nitrate / TNT ratio above about 5: 1. For economic reasons, one will use as little TNT as possible; the minimum amount of TNT is approximately 15%. The ratio of ammonium nitrate to TNT to water = 68:17:15 has proven to be particularly effective. These details refer to aluminum-free mixtures of ammonium nitrate, TNT and water. However, if part of the TNT is replaced by aluminum powder, the ammonium nitrate-TNT ratio can be increased considerably. In order to get by with as little water as possible, a mixture of coarse and fine Al is preferably used, preferably in a ratio of 1: 1. For example, the coarse Al can have a grain size of 0.5 to 6.7 mm, while the fine Al increases more than 80% passes through a sieve of 0.147 mm mesh size and more than 30% through a sieve of 0.044 mm mesh size. The A1 can be added in an amount of up to 100 parts per 80 parts of the mixture of TNT and ammonium nitrate.

To prevent leaching, a water binder, e.g. B. Wheat flour, mill products, pregelatinized starch products, cellulose and fiber materials be added in an amount of 1 to 10%. In this case you can go to 27 1110 Water can be added.

Furthermore, the mixed explosive according to the invention can be urea and / or Metal nitrates, e.g. B. sodium nitrate, in an amount of about 1 to 25%. These substances lower the melting point and set that for slurrying required amount of water.

Those in the practice of the invention and in the following Examples of mixed explosive samples examined had a density of approximately 1.0 g / cm3, a critical diameter (or smallest diameter in which the detonation propagates) from 5 to 7.5 cm in the dry state and required For detonation, an impact charge made of pressed tetryl (short for tetranitromethylaniline [see. R ö m p p, Chemielexikon, 1952, p. 1787]) of at least 5 cm in diameter and 10 g weight. The measured speed was 4050 at a 13 cm diameter m / sec.

In the examples, percentages are given in percent by weight, unless otherwise stated. Example 1 A mixture of 2211 / o granulated, d. H. in a known manner by sprinkling the melt or concentrated solution in tall towers granulated ammonium nitrate, 65% coarse TNT with a particle size from 2.4 to 6.7 mm and 13% water had a density of 1.4 g / cm3 and detonated at a critical diameter of 2.5 cm with a smallest impact charge 20 g of pressed tetryl with a diameter of 2.5 cm. The speed of detonation at 13 cm diameter was 5800 m / sec. Example 2 A mixture of 64 "/ g, granular Ammonium nitrate, 21% coarse TNT (particle size 2.4 to 6.7 mm) and 15% water, the in this case the minimum amount necessary for slurrying, had a density of 1.41 and a critical diameter of 10 cm. She was with the smallest of blows of 100 g of pressed tetryl with a diameter of 5 cm to detonate and possessed a detonation speed of 5150 m / sec at 13 cm diameter. Example 3 A mixture of 70% granular ammonium nitrate, 1711 / o coarse TNT (particle size 2.4 up to 6.7 mm) and 1311 / o water had a critical diameter of 13 cm and was 1: 1 mixture of TNT and cast with a smallest impact load of 160 g Detonate PETN with a diameter of 5 cm.

Similar results as in Examples 1 to 3 were obtained using flaky TNT. Example 4 Experiments were conducted in which a dry mixture of 40: 30: 30 ammonium nitrate-AI-TNT was poured (grain size of the TNT 3.3 to 4.8 mm) in a clear saturated solution of ammonium nitrate. The Al was either an intimate mixture of equal parts of coarse and fine Al or consisted entirely of coarse Al. The ammonium nitrate was a 50:50 mixture of fine (grain size less than 3 mm) and coarse material granulated in the trickle tower. The finished explosive charge had a final density of 1.59 and had the following typical composition: ammonium nitrate ...... 42% A1 ................... 32% TNT. . . . ........... . 161 / o water ................ 10 ± 21 / o In each case, the mixture detonated completely and vigorously when an impact load of 160 g of a poured 1: 1 mixture of TNT and PETN was used at the foot of the 23 cm thick and 127 cm (± 13 cm) long cargoes. Example 5 A mixture of 35% ammonium nitrate, 30% coarse TNT (grain size over 95 mm), 20% fine Al and 15% water was placed as sludge at the bottom of a pipe so that it did not get stuck with water mingled. It had a density of 1.7 g / cm3 and a detonation speed of 5000 m / sec. The critical diameter of a similar charge of 45% ammonium nitrate (mixture of coarse and fine material), 40% coarse TNT of the same grain size and 15% water was less than 5 cm, and the smallest impact charge was 20 g of pressed tetryl with less than 2.5 cm Diameter. With a similarly composed charge of 35 parts of granular ammonium nitrate, 30 parts of granular TNT (particle size 2.4 to 6.7 mm), 20 parts of coarse Al and 15 parts of water, the smallest impact charge was 60 g of tetryl with a diameter of 2.5 cm, the critical diameter 10 cm and the detonation speed 5750 m / sec. Example 6 Sodium nitrate can also be used in the slurries according to the invention. For example, the slurried mixture of 37 parts ammonium nitrate, 20 parts sodium nitrate, 10 parts TNT, 25 parts Al and 10 parts water when using coarse TNT (grain size 2.4 to 6.7 mm) and fine, mostly through a sieve Al with a mesh size of 0.74 mm had a density of 1.79 g / cm3 and could be detonated in 23 cm charges with 160 g of a 1: 1 mixture of TNT and PETN poured here. Smaller detonators and charge diameters were not investigated with this composition. Example 7 Granular ammonium nitrate,% ............. 65 59 59 Coarse-grained TNT (grain size over 0.5 mm),% 20 - - Flake TNT, ° / o ....... - 25 - Fine-grain TNT (grain size less than 0.4 mm), 0/0 - - 25 Water, a / o .............. 15 16 16 Density ................. 1.40 1.40 1.36 Minimum detonator ........ 40 40 320 *) Tetryl dl (cm) ................. 10 7.5 failure-15 Here a detonator was made from 50% TNT and 50% Used pentaerythritol granitrate, which is much stronger when the tetryl detonator and still was unsuccessful. This example again shows that with the same TNT content in the ammonium nitrate TNT sludge, the coarse-grained or flaky TNT is much better than the fine-grain TNT. The sludges with 25% fine TNT did not burn off at all, while those with 25 a / o flaky TNT could be detonated with only 40 g of pressed tetryl and a diameter of only 7.5 cm. Even with only 20% coarse-grained TNT in the ammonium nitrate-TNT-water sludge, the sensitivity is high enough that the sludge could be detonated with only 49 g of pressed tetryl as a detonator at a diameter of 10 cm. Example 8 Granular ammonium nitrate, 0/0 ............ 64.5 50.5 50 Coarse-grained TNT (grain size 1.2 to 1.7 mm), 0/0 16.2 - - Flake TNT, 0/0 ...... . - 31.5 - Fine-grain TNT (grain size less than 0.4 mm), 0/0 - - 31 Water,% ............. 19.3 18.0 19 Density ................ 1.37 1.41 1.26 Minimum detonator ....... 320 *) 20 320 *) Tetryl d, (cm) ................ 15 4.5 15 *) See note to the table of example 7. This example shows the following: The same ignition sensitivity is achieved with only 16.2% coarse-grained TNT of the optimal grain size (1.17 to 1.65 mm) as with almost twice as much (3111 / o) fine-grained TNT.

While the minimum amount of fine-grained. TNT that you need to get the Detonating ammonium nitrate TNT water sludge between 25 and 31%, with coarse-grained TNT, on the other hand, this sludge with only 16% Detonate TNT.

With the same percentage of TNT, flaky TNT is far more effective than fine-grained TNT TNT to make the mud mixes sensitive to ignition.

Similar results as in the previous examples were obtained, when instead of pure TNT so-called tols were used, i.e. pourable mixtures of TNT with other explosive substances, such as penaerythritol tetranitrate or ammonium nitrate. In all cases, the mixtures were found in which the highly explosive component, d. H. the TNT-containing Tol, had a grain size of over 0.5 mm, the mixtures with Far superior to fine TNT components in terms of ignition sensitivity.

It is also stated that the subjects of claims 3 to 5 no independent protection is granted.

Claims (5)

Claims: 1. Mixed explosive made of ammonium nitrate, an explosive component and water, d u r c h e -k e n n n z e i c h n e t, that it is an explosive component Trinitrotoluene in an amount of about 15 to 65%, water in an amount of about 5 to 20.1 / 9 and the remainder contains ammonium nitrate, with the trinitrotolual in coarse-grained Form with a particle size greater than 0.5 mm or in flaky form. 2. Mixed explosive according to claim 1, characterized in that the trinitrotoluene is present in a particle size of about 1.2 to 1.7 mm. 3. Mixed explosives according to one of the preceding claims, characterized in that it additionally or as a replacement for part of the TNT contains aluminum. 4. Mixed explosives after Claim 1, 2 or 3, characterized in that it contains 1 to 10% water-binding agent and contains a total of 27% water. 5. Mixed explosives according to one of the preceding Claims, characterized in that it is approximately 1 to 25 'IM metal nitrate and / or Contains urea. Publications considered: German Auslegeschrift No. 1009,990; British Patent No. 597 716.