DE455054C - Process for the production of detonators - Google Patents

Description

Process for the production of detonators. So far, detonators have been manufactured in such a way that a number of detonator sleeves are inserted into a so-called spoon made of hardwood or hard rubber. The nitro bodies are then loaded and then pressed with a pressure of about 300 kg per cm2. It is not possible to use significantly higher pressures, as otherwise the sleeves will give way to the side.

Since in this pressing process the cubic density of the nitro body is low, and thus also its explosion speed, stick to the previous one Manufacturing process defects, the elimination of which is the purpose of the invention, in which the well-known fact that explosive devices with a cavity at the bottom are a show much greater effect than those with: flat bottom in detonators is also used, which are manufactured according to a special process.

Detonators are already known whose bottoms are pressed in the load can be drawn in by means of a mandrel about 7 mm high, but in practice, as a result of piercing the bottom of the detonator, water and others phlegmatizing substances can easily penetrate the cargo. Also the one A higher initial strength of these capsules could not be determined in detailed tests will. On the contrary, it was observed that a normal detonator No.8 is at least equivalent to these new capsules, and in many cases even superior was.

The experiments involved comprised a series of shots of 20 rounds of a normal No. 8 capsule, and 20 rounds of the detonators produced according to the known method. Both types of capsules were loaded with 0.85 g of trinitrotoluene and 0.5 g of popping salt and were shot onto cartridges 113 mm in length and 95 g weight, desensitized with 3 percent castor oil. The results were as expected. The normal detonator capsule 8 produced 9 complete detonations with 2o rounds, 3 partially with the formation of whitish smoke and 8 incomplete detonations with white smoke formation and residues of unreacted explosives. The known capsule produced 2 complete detonations with 2o rounds, 1 partial detonation with the formation of whitish smoke, on the other hand 17 incomplete detonations with heavy smoke formation and explosive residues.

The purpose of the invention is to manufacture a detonator that does too is provided with a cavity at the bottom and as a result of a special procedure all detonators currently on the market with the same initial capacity by far, and also an important one from an economic point of view Metal saving is achieved. The detonators manufactured using this new process are namely much shorter, thereby lighter, which means transport and packaging costs significantly reduced and easier handling is achieved.

It has now been found that if you remove the detonators before pressing inserts into cylindrical close-fitting matrices, loads onto them, and each with one movable ram from above and below with a pressure of up to 300o kg per em2 presses, one obtains a much higher cubic density of the secondary charge and the lower ram in this case the bottom of the detonators by means of a corresponding formed cam about 3 to 5 mm. By using the matrices becomes actually achieves a much higher cubic density of the secondary charge, because of the leeway that the capsules have in ordinary loading spoons and the making the higher pressure completely illusory by placing the detonators sideways evade, here completely absent and the capsule tightly enclosed the higher Can withstand pressure. In addition, the detonator bottoms remain with this new process absolutely preserved, so that the pit water or other phlegmatizing substances cannot penetrate the cargo.

The new capsule is also particularly noteworthy from an economic point of view, in that the detonator cases can now be significantly shorter due to the strong compression of the secondary charge and, if lead azide or lead azide-containing primers are used, also the primary charge, and still have the empty space of 1 5 to 5 required to strangle the fuse Keep 1 6 mm. If one starts from the knowledge that the metal processed into detonators is absolutely lost at the moment of ignition, the economic advantage, which lies in the metal savings of detonators produced by this method, is easy to see. Of course, the transport and packaging costs are also significantly reduced due to the smaller size of the detonators. The handling of the detonator transport crates is also made much easier.

Practical tests have now shown a significantly higher initial strength of these new detonators. The bombardment of phlegmatized explosives, which can now be seen as a Witte's criterion for the ability to initiate a detonator, resulted in these new explosive detonators being completely superior to all detonators that were commercially available up to that point. The series of firings here comprised 24 rounds of Trinitrotolt® olspreng cartridges, 1 1 3 mm in length and 95 g in weight, desensitized with 3 percent castor oil. All experimental explosive cartridges were made from the same manufacturing mix. The normal detonator capsule No. 8, loaded with 0.85 g of tetranitromethylaniline and 0.3 g of azide-trizinate mixture, resulted in 24 shots 9 complete, 4 partial detonations with weak flame and smoke formation, on the other hand ii incomplete detonations with heavy smoke formation and explosive residues. The new explosive device with the same charge, in stark contrast to this, also delivered 24 complete detonations with 24 rounds. The much larger bulge of the Trauzl lead mortar also indicates the complete superiority of the new explosive detonators.

Claims (1)

PATENT CLAIM: Process for the production of detonators with a Cavity at the bottom of the capsule, characterized in that the secondary charge is in the detonator cases by means of a high pressure at the same time with a movable stamp from above and the bottom is strongly compressed in corresponding dies, with the lower punch at the same time the blasting capsule base in a known manner you form a hollow body gives.