DE1092357B - Process for the waterproofing of explosives - Google Patents

Description

Process for the hydrophobization of explosives The hydrophobization is known of water-soluble solid substances, e.g. B. Alkaline nitrates, for the production of weather explosives, e.g. B. by fatty! Acidic salts. This hydrophobizing Salts were previously mixed with the water-soluble substances during grinding, pouring, Melting, mixing and dosing, but also through a separate operation.

In this mixing process, however, only incomplete water repellency occurs because this treatment results in patchy and non-homogeneous layers on the Explosive components are generated.

A particular disadvantage of these methods is that the explosive Weather explosives data z. B. very unfavorably influenced by fatty acid salts will.

It is also known to provide solid, hygroscopic alkali metal hydroxides to hydrophobize atmospheric moisture by non-hygroscopic but water-soluble Alkali salts, which are formed by the reaction of esters with the alkali hydroxide surfaces to be protected develop. It is even important that the alkali salts formed are water-soluble because otherwise they remain undissolved when the photographic developer is dissolved would. This means that no water repellency can be achieved against liquid water will.

Such coatings resulting from esters are incomplete because the water-immiscible esters, more or less moist alkalis or inorganic ones Do not completely wet the salt crystals. It is therefore proposed in this context that apply a second protective layer by re-treating with ester. but even then, the protection against water vapor is only sufficient for some time.

According to the invention, the crystalline water-soluble constituents can be used make explosives surprisingly hydrophobic even against liquid water, without blasting data, in particular the detonation transmission, get much worse. Accordingly, the hydrophobizing substances are on generated on the surface of the crystalline water-soluble constituents in such a way that that first the hydrophilic reaction component is applied to the crystal surface and then only the component containing the hydrophobing portion is reacted with the hydrophilic component. As a hydrophilic reaction component can inorganic salts, such as. B. calcium chloride, can be used as a reaction component, which contain the water-repellent component, fatty acid salts.

This ensures that the hydrophobing molecules are directed in the most favorable way, that is, in such a way that the hydrophobic part of the molecule faces the attacking water molecules and the hydrophilic part sits on the water-soluble crystal. This hydrophobization is thus achieved in that the hydrophobizing molecules, for. B. calcium stearate molecules, can only arise on the surface of the substance, for which z. B. first aqueous calcium chloride solution mixed with the substance, then mixed with stearic acid solution and then neutralized, z. B. by ammonia. The calcium chloride solution tends to distribute itself homogeneously. After the reaction with stearic acid, the hydrophobing calcium stearate molecules are homogeneous and distributed in the most favorable manner for hydrophobing, if the concentration is correct, even in a monomolecular layer. example 1 2360 g potash nitrate, ground with additives of 0.04% tetryl 1240 g of ammonium chloride 0.2371 g calcium chloride # 2 water 0.2200 g zinc chloride 1.8365 grams of stearic acid ammonia 12 g alumina hydrate 347.5 g blasting oil ( 60:40) 0.4 g collodion wool 4 g of Aerosil 38 g guar flour A solution of calcium chloride and zinc chloride in water and ethanol (95%) was sprayed and mixed with potassium nitrate and ammonium chloride. Thereafter, stearic acid dissolved in ethanol (95%) was sprayed in and mixed, ammonia was blown in and mixed. It was then mixed with alumina hydrate, blasting oil, which had been mixed with collodion wool and Aerosil, and guar flour.

This mixture creates calcium and zinc stearate which act as hydrophobing agents Substances.

Instead of the fatty acid and neutralizing agent according to Example 1, it is also possible to use a fatty acid salt, for example ammonium stearate. Example 2 2360g potassium nitrate, 0.04% tetryl 1240 g of ammonium chloride 0.2371 g calcium chloride # 2 water 0.2200 g zinc chloride 1.9750 grams of ammonium stearate 12 g alumina hydrate 347.5 g explosive oil (60:40) 0.4 g collodion wool 4 g of Aerosil 38 g guar flour To potassium nitrate, ammonium chloride, calcium chloride and zinc chloride solution, prepared and mixed as in Example 1, 1.9750 g of ammonium stearate, dissolved in ethanol (95%), were sprayed and mixed. Then, as in Example 1, alumina hydrate, explosive oil, etc. were mixed in. This mixture creates calcium and zinc stearate as hydrophobing substances.

In order to show that these water repellent methods are in any case better than what has been customary up to now, a comparison mixture has been used in accordance with the process customary up to now manufactured.

It contains the same hydrophobizing salts and also the same amount of them as the mixtures described as Examples 1 and 2. Comparison mixture 2360 g potash nitrate, ground with additives of 0.0411 / o tetryl 1240 g of ammonium chloride 0.9795 g calcium stearate 1.0205 g zinc stearate 12 g alumina hydrate 347.5 g blasting oil ( 60:40) 0.4 g collodion wool 4 g of Aerosil 38 g guar flour Calcium stearate and zinc stearate, ground in a glazed porcelain mortar, were sprinkled with potassium nitrate and ammonium chloride and mixed for a correspondingly long time. Then, alumina hydrate, explosive oil, etc. were mixed in as in Example 1. The results were shown in Table 1. Table 1 1 Beis i pie 1 2 veggie mix Diameter of the cartridge. .. ...... ... . .. .... . . . . .. .. ... 30 30 30 Cartridge density, g / cm3 ................................. 1.35 1.34 1.34 Lead block bulge according to Trauzl, cm3 / lOg .......... 79 80 72 Hess lead block compression, mm. . . . . . . . . . . . . . . . . . . . . 5.1 4.9 5.4 Water resistance, cm / min. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100/60 50760 less than 20/60 Detonation transfer, cm on sand. . ... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . over 100 over 100 75 in a cardboard tube (40 mm diameter). . . . . . . . . . . . . . . . . . 110 80 25 Water resistance 50/60 means that four cartridges, stored 50 cm below the water level for 60 minutes, then detonated completely, if lying in the same axis direction and lying next to each other in the air, bedded on sand and ignited by a detonator Al 3 in the first cartridge.

Detonation transmission 85 means that two cartridges, embedded 85 cm from each other in the same axial direction, still detonated when one of the two cartridges was detonated by an Al 3 detonator. Example 3 This explosive has the same composition as that described as Example 1. With him, however, the stearic acid solution was sprayed first and then the calcium chloride and zinc chloride solutions. It was then neutralized by ammonia. Example 4 This explosive has the same composition as that described as Example 2. In his case, however, the ammonium stearate solution was sprayed in first and then the calcium chloride and zinc chloride solutions. The results are shown in Table 2. Table 2 example 3 4 Cartridge diameter .. 30 30 Cartridge density, g / cm3 ..... 1.30 1.30 Lead block bulge according to Trauzl, cm3 / 10g .. 78 78 Water resistance, cm / min. . . none at none at 2Q / 15 20/15 Detonation transmission in Cardboard tube (40 mm knife) ................ 120 70 This shows that a wrong order in the addition of the components from which the hydrophobizing substances are to be formed does not lead to the surprising water resistance, because the hydrophobizing molecules are not directed in the most favorable manner according to the invention. It is particularly favorable that, according to the invention, it is now also possible to start from water-soluble components which can be easily distributed on the crystal to be hydrophobicized. Only then does the water-insoluble, hydrophobizing substance arise from the water-soluble components. The following example may serve for this purpose. Example 5 2360 g potash nitrate, ground with additives of 0.04% tetryl 1216 g ammonium chloride 24 g ammonium chloride, ground 0.67 g calcium chloride - 2 water 2.023 g of alkyl (C ") iminodiacetic acid sodium 12 g alumina hydrate 347.5 g blasting oil ( 60:40) 0.4 g collodion wool 4 g of Aerosil 50g guar flour A solution of calcium chloride in water was sprayed and mixed with potassium nitrate and ammonium chloride. Thereafter, sodium alkyliminodiacetic acid dissolved in water was sprayed in and mixed. It was then mixed with alumina hydrate, blasting oil, which had been mixed with collodion wool and Aerosil, and guar flour.

This mixture produces calcium alkyliminodiacetic acid as a hydrophobing substance. Comparison mixture 2360 g potash nitrate, ground with additives of 0.04% Tetry 1 1216 g ammonium chloride 24 g ammonium chloride, ground with addition set of alkyliminodiacetic acid Calcium 2 g of alkyl (C1.) Iminodiacetic acid Calcium 0.533 g sodium chloride 12 g alumina hydrate 347.5 g blasting oil ( 60:40) 0.4 g collodion wool 4 g of Aerosil 50g guar flour 24 g of ammonium chloride were triturated with 2 g of calcium alkyliminodiacetic acid, then mixed with potassium nitrate and the remaining ammonium chloride and sprayed with an aqueous solution of sodium chloride, then mixed with alumina hydrate, blasting oil which had been stirred with collodion wool and Aerosil, and guar flour.

The results are shown in Table 3. Table 3 Example s comparative mixture Diameter of the cartridge. . 30 30 Cartridge density, g / cm3 ..... 1.32 1.33 Lead block bulge according to T rauz 1, cm3 / 10 g. . 68/74 70/65 Lead block compression according to Hess, mm ......... 4.3 4.3 Water resistance, cm / min ... 100/240 50/30 Detonation transmission in Cardboard tube (40 mm knife) ................ 100 80

Claims (3)

PATENT CLAIMS: 1. A method for hydrophobing crystalline water-soluble components of explosives, characterized in that the hydrophobizing substances are generated on the surface of the crystalline water-soluble components in such a way that first the hydrophilic reaction component is applied to the crystal surface and then only the hydrophobizing component Part containing component is reacted with the hydrophilic component. 2. The method according to claim 1, characterized in that inorganic salt solutions can be applied to the surface of the crystalline water-soluble components and then salts of fatty acids. 3. The method according to claim 1, characterized in that first inorganic salt solutions are reacted on the surface of the crystalline water-soluble constituents and then free fatty acids by subsequent treatment with ammonia or amines. Documents considered: German Auslegeschrift No. 1 024 940.