DE3804397C1 - Process for producing compressed explosive charges - Google Patents

Abstract

To obtain a compressed explosive charge of high density and low sensitivity, an explosive material having a bimodal grain size distribution is used, the coarse grain fraction having a mean grain size from 20 to 80 mu m and the fine grain fraction having a mean grain size from 2 to 10 mu m, the coarse grain fraction/fine grain fraction weight ratio being 3-10 : 1.

Description

The invention relates to a method for producing pressed Explosive charges made of crystalline coated with a binder Explosives with bimodal grain.

As a binder for pressed charges such. B. wax, plastics or rubber, e.g. B. BUNA rubber used. The binder serves at the same time for desensitization, d. H. it sets the punch and Sensitivity to friction. On the other hand, the proportion of binder the charge should be as low as possible, e.g. B. only 2 to 8% by weight amount to a high loading density and thus high performance achieve.

Bimodal or multimodal, d. H. from a coarse grain fraction and a fine grain fraction or from several grain fractions of different sizes compound grits used. They lead to a higher one Packing density and thus loading density compared to monomodal grain sizes. A well known bimodal granulation of high explosive explosives, such as Octogen or hexogen, e.g. B. from a coarse grain fraction a grain size between 30 and 800 microns and a fine grain fraction with a grain size of less than 160 microns together, the Weight ratio of the coarse grain fraction to the fine grain fraction about 2: 1 is.

Limiting the grain size of the coarse grain fraction to z. B. at most 800 µm is required because the bulk of the explosive strongly affects the sensitivity of the load. Actually, or impact loads, e.g. B. caused by an intrusive  Projectile, a coarse grain of a few 100 microns in diameter, so comes practically the high sensitivity of the pure explosive to wear, d. H. the small enveloping amount of binder is no longer in the Able to effectively dampen the reaction initiated in the grain, so that the Explosives explode or detonate.

Pressed granules containing octogen containing 5% by weight BUNA rubber as a binder with a bimolar grain (Coarse grain fraction 30 to 800 µm; fine grain fraction less than 160 µm; Weight ratio of the coarse grain fraction to the fine grain fraction 2: 1) one Impact sensitivity of 7.5 joules and a sensitivity to friction of 352 Newtons. The density after pressing with a pressure of 1.5 kbar is 1.79 g / cm³.

A further reduction in sensitivity to impact and friction by reducing the grain size of the coarse grain fraction stands in the way that thereby increasing the surface area of the explosive. This requires a larger amount of binder to coat the explosive grains or to desensitize, i.e. a reduction in the loading density or Performance through a higher proportion of binder.

The object of the invention is the without affecting the performance To reduce the sensitivity of a compressed explosive charge. this will achieved according to the invention by the measures specified in claim 1. Advantageous refinements of the characterized method according to the invention.

Surprisingly, it was found that the Sensitivity of the pressed granules by reducing the grain size of the Coarse grain fraction like the fine grain fraction of a conventional bimodal Can significantly reduce grain size to about 5 to 20 times without that an increase in the proportion of binder is required, if a relatively large proportion of the coarse grain compared to the fine grain used becomes.  

The coarse grain fraction of the grain size according to the invention has preferably a grain size between 20 and 160 microns, particularly preferred between 20 and 80 µm while the grain size of the fine grain fraction preferably at most 16 µm, particularly preferably at most 8 µm and in Average is 2 to 10 microns, preferably less than 5 microns.

Due to the bimodal granulation according to the invention with a fine grain fraction with an average grain size of 2 to 10 microns, preferably smaller than 5 µm, ie a "fine grain fraction", in a relatively small amount, are both performance and security requirements and the processability of the compressed explosive charge, d. H. height Compression at a relatively low pressure, certainly met.

example

Octogen with a bimodal grain with a coarse grain fraction with a Grain size between 20 and 160 µm and a fine grain fraction with a Grain size of less than 10 microns and with a weight ratio of Coarse grain fraction to the fine grain fraction of 5 was with 5 wt .-% BUNA rubber covered. The press granules were then a blow and subjected to a friction sensitivity test and with a pressing pressure pressed at 1.5 bar. The results are in the table below specified.

For comparison, this table also shows the values with conventional octogen pressed granules were obtained, the one bimodal grain with a fine grain fraction with a grain size of 30 to 800 µm and a fine grain fraction with a grain size smaller than Has 160 microns, the weight ratio of the coarse grain fraction to Fine grain fraction was 2: 1.

As can be seen from the table, the one produced according to the invention Explosive charge significantly reduced the sensitivity to impact and also a decrease in the sensitivity to friction, the  Density and therefore performance compared to that of the prior art manufactured charge is essentially the same.

In the present context, the information on grain size refers to Measurements made using the laser beam method.

Claims (5)

1. A process for the production of compressed explosive charges from crystalline explosives with a bimodal grain encased in a binder, characterized in that a bimodal grain with a coarse grain fraction with an average grain size of 20 to 80 µm and a fine grain fraction with an average grain size of 2 to 10 µm is used is, the weight ratio of the coarse grain fraction to the fine grain fraction is 3 to 10: 1. 2. The method according to claim 1, characterized in that a bimodal grain with an average grain size of the coarse grain fraction of less than 50 µm is used. 3. The method according to claim 1 or 2, characterized in that a bimodal grain is used in which the weight ratio of the Coarse grain fraction to fine grain fraction is 4 to 6: 1. 4. The method according to any one of the preceding claims, characterized characterized in that a proportion of binder is used which is less than 8% by weight of the pressed load. 5. The method according to any one of the preceding claims, characterized characterized in that as a binder BUNA rubber and as an explosive Octogen or hexogen is used.