DE1047091B - Dynamite Composition - Google Patents

Description

Dynamite Composition The invention relates to improved dynamite compositions.

The technically most important dynamite compositions essentially exist from a highly explosive sensitizer and a mixture of inorganic, oxidizing agents Salts and flammable substances containing carbon. The explosive sensitizer usually a liquid, explosive nitric acid ester, e.g. B. \\ 'itroglycerin, facilitates ignition of the composition and provides the requisite explosive force. The oxidizing agents and the flammable substances contribute to the explosive power of the composition and also control the formation of the gaseous combustion products so that undesirable Gases do not arise or only to a lesser extent. Other additives, such as gelling agents, Antidotes for acids, plasticizers and the like are also often made up of dynamite contain.

The sensitivity or reproductive capacity of a dynamite composition is closely related to the density of the composition, the ratio being that with increasing density the sensitivity decreases, if all other factors stay the same. For the above reasons, there have been many types of ingredients with low density and examined for their usefulness in dynamite compositions tested. The low density ingredients are intended to appropriately enhance the performance of the Increase composition and should of course not give it any unfavorable properties to lend. The density of the nitroglycerin ester cannot be changed significantly, and the density of the inorganic, oxidizing salts is only light. Changes accessible. Therefore, the density must be determined primarily by suitable choice of the combustible Components are regulated if the desired results are to be achieved.

Carbon-containing substances such as B. Holzpu.lpe and various vegetable Fibers have a relatively low density in dry form. they are but so absorbent that the nitroglycerin gets into the pulp or fibers so strongly absorbed, that the composition obtained does not just turn has a high density, but also becomes dry and therefore heavy in cartridges is to be filled. Puffed up grains have been found to be less absorbent as the pulps and the fibers proved so that the density decreased and at the same time the filling capacity can be maintained. However, there is one in storage increasing absorption of the nitroglycerin even when using this bloated one Grains, thereby losing the effectiveness of the low density component. They also absorb when stored moist or when immersed in '' water so much water under considerable pressure that the reproductive power is strong is reduced.

The object of the invention is therefore to create an improved dynamite composition, which when immersed in water, even under high pressures, the ability to reproduce does not lose.

According to the invention, a nitroglycerin is characterized as a sensitizer Dynamiizusa.mmensetzun.g contained in that they are part of the low Density at least 0.25 percent by weight of an insoluble in water and in nitroglycerin, thermosetting synthetic resin in the form of hollow, spherical balloons with between about 2 and 360 microns in diameter, the bulk density this balloon is less than 0.3 glem. Other flammable components are usually still present, the amount and type of which depends on the composition set requirements.

The sensitizer is expediently a nitrated mixture of glycerine and ethylene glycol. Such nitrate mixtures as well as other nitrated mixtures of Glycerin and compounds such as sugar, polyglycerin, Palyäthyleneglycol, etc. are the specialist. generally known under the term "nitroglycerin". Accordingly the term "nitroglycerin" is of course to be understood here. (The inventive Composition usually contains 20 to 80 percent by weight nitroglycerin.) Many Types of flammable components with high density (0.6 g or more per cc) known to the person skilled in the art. Typical flammable components with high Density are starch, corozo flour, apricot kernel flour, walnut shells.-meh'l, soybean flour and wheat flour. Flammable substances often used in dynamite compositions with low density are among other things, besides the bloated grains, wood pulp, ground cork and molasses extract. The incorporation of flammable substances with both high as well as low density in addition to the resin balloon belongs in the Scope of the invention. This allows the oxygen balance to be regulated to control the development of smoke-and-the explosive power, without the need for large quantities the resin balloons are necessary. This is from an economic standpoint as well also important for regulating the density. Appropriately, the density of the dynamite composition should be be greater than 1 - so that it can be easily submerged in water. The salary the composition according to the invention of burnable substances is generally between about 5 and 20 percent by weight.

The composition according to the invention generally contains 10 to 70 percent by weight of an inorganic, oxidizing salt. Usually in The salts used in explosives are ammonium nitrate and sodium nitrate, as these are cheap and have the desired reactivity with flammable substances. additions such as acid killers, e.g. B. Lime, and gelling agents. e.g. nitrocellulose, are also present in the required quantities.

The invention is particularly directed to gelatin dyn: amite compositions applicable, as these are most likely to lose their reproductive capabilities on storage, and because gelatin compositions are most commonly used when having water resistance is desired. The gelatin dynamite compositions typically contain 0.5 to 6 percent by weight nitrocellulose as a gelling agent for gelatinizing the titroalycerin.

The compositions according to the invention can be used in conventional mixing devices produced and bottled in the usual way using the known Varrichtungen will. The Harz Hallönchen are extremely resistant despite their very thin walls against breaking. and therefore withstand the mixing and filling action. Because Their smooth spherical shape allows them to be thoroughly mixed into the dynamite composition will.

The resin balloons are most easily made from a phenolic, l-fo @ rmaldthyd resin composition, as described in the following examples. Resin balloon. from a urea formaldehyde: ehyd resin are commercially available and have about the same physical properties. The resin balloons are technically used Use as floating ceilings made on volatile petroleum to get through Reduce losses caused by evaporation. Neither the composition of the resin The manufacture of the little balloons is also within the scope of the present invention. The only condition is that the resin is insoluble in water and in nitroglycerin. The particle size and bulk density, however, are important. Particle with a Diameters in excess of about 360 microns can be used both in manufacture and Forces occurring underwater also when using the Dyna.mite composition only withstand if they are relatively thick-walled. With increasing wall thickness however, the bulk density of the balloon increases, and so do the cavities in the balloon lose their importance as localized "hot spots" that result from compression of a Gas when igniting the dynamite. Resin balloon with a diameter with less than about 2 microns does not contain enough entrapped gas to produce the desired To preserve reproductive power. The condition that the bulk density is less than 0.3 g / ccm is a control for the wall thickness and thus also for the size of the cavity in the balloons.-The amount of resin balloons must be at least 0.25 percent by weight, based on the total composition, so that their reproductive capacity is improved. Because the resin itself is flammable can be used in very large quantities without adversely affecting the explosive power of the dynamite be used; because the resin balloons are much more expensive than others known flammable substances and since using more than about 4 percent by weight, based on the total composition, no benefit obtained, contain the preferred Compositions according to the invention between 0.25 and 4 percent by weight of the resin balloons.

The following examples explain the invention without, however, being restricted to the information given therein. Ingredients Composition (o / o) - A I- BICDIEFIGIH Nitroglycerin '). ..... ....... 50.0 50.0 50.0 40.0 40.0 40.0 30.5 30.0 Nitrocellulose ... .. .. ................ 2.2 2.2 2.2 1.8 1.8 1.8 0.6 1.0 Sodium nitrate ....................... 32.8 32.8 32.8 29.3 29.3 29.3 30.2 [26.9 Ammonium nitrate .........: .......... - - - 14.0 14.0 14.0 26.5 31.0 Lime ........... .............. ..... 0.5 0.5 0.5 0.4 0.4 0.4 0.5 0.4 Starch ................. - ......... 4.5 6.0 4.5 6.0 5.5 5.5 6.1 4 , 7 Very dense flour . . . . ............... 4.3 6.5 6.0 6.5 5.0 5.0 4.6 4.0, Wood pulp ....... ..... ... .. ....... - 1.0 - 1.0 - - - Bloated grains. .. ... .. .. .. ... 5.7 - - - - 4.0 1.0, - Resin balloons2) ....................... - 1.0 4.0 1.0 4.0 - - 2.0 Total .... 100 100, 100 100 100; 100 100 100 ') Nitrated mixture of 800/9 glycerine and 2011 / o ethylene glycol. 2) The resin balloons used are commercially available and are made from a phenol-formaldehyde composition manufactured. You have the following data: Bulk density ................................................. ........ -0.138 L '/ cc Particle density. ... . . ... . . . . . . . . . . . . . . . . . -. . . . . . . . . . . . . . 0.149 ;; / ccm in oil - Average particle size (diameter). . . . . . . . . . . . . . . . . . . . . . . . . . 0.0033 cm Size range (diameter). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.0005 to 0.0091 cm The gelatin dynamite compositions listed in the table above were prepared in a conventional manner in a standard facility and packaged in approximately 61 cm long sleeves, 5.7 cm in diameter. The sleeves consisted of spirally wound tubes sprayed with paraffin. The weight of each cartridge was approximately 2.3 kg.

Pressure and propagation speed test results became so obtained by connecting two cartridges by means of a cardboard tube at the ends together connected, attached an electric detonator to the outer end of one of the cartridges, at a certain distance from the second cartridge two signal elements (small Sleeves, which close a circuit when folded) attached and the brought the whole assembly into a steel tube with a diameter of 10.2 cm. the Ends of this tube were hermetically sealed, and those to the igniter and the signaling elements leading wires ran between two seals. The tube was then filled with water filled and immersed in the test water container, whereupon more water is added to the Pipe has been pumped in until the desired pressure is achieved. The one to the signal elements leading wires were attached to a time recorder and the wires leading to the detonator were connected to a current duel. After submerging at the specified Pressure for the specified period of time ignited the detonator and recorded made. The results were as follows: Composition A. A fresh sample exploded at a speed of 2400 m per second after submerging for 15 minutes, at a pressure of. 17.6 kg / cm2.

A sample stored for 1 month at 38 ° C in a humid atmosphere planted only 10.6 kg / cm2 after immersion for 15 minutes at a pressure of Detonation did not proceed and exploded at a speed of 4880 m per second after immersion for 15 minutes at 7 kg / cm2.

Composition B. A fresh sample detonated at one rate of 6350 m per. second after submerging for 15 minutes at a pressure of 17.6 kg / cm2 and at 5600 m per. second under the same conditions after 1 month of storage at 38 ° C in a humid atmosphere.

Composition C. A fresh sample detonated at one rate of 5900 m per second after submerging for 15 minutes at a pressure of 17.6 kg / cm2 and at 5200 m per. second under the same conditions after 1 month of storage at 38 ° C in a humid atmosphere.

Composition D. A fresh sample detonated at one rate of 6680 m per second after 15 minutes of immersion under a pressure of 17.6 kg / cm2 and at a speed of 5640 m per second under the same conditions after 1 month of storage at 38 ° C in a humid atmosphere. After 18 hours Immersion at a pressure of 17.6 kg / cm2 detonated a 1 month at 38 ° C in Sample stored in a humid atmosphere at a speed of 6190 m per second.

Composition E. A fresh sample detonated at one rate of 5520 m per second after 15 minutes of immersion at a pressure of 17.6 lcg / cm2. A sample stored for 1 month at 38 ° C in a humid atmosphere detonated with a Speed of 6040 m per second after being immersed for 18 hours with one pressure of 17.6 kg / cm2.

Composition F. The fresh sample detonated at one rate of 5900 m per second after submerging for 15 minutes at a pressure of 17.6 kg / cm2. To. Storage for 1 month at 38 ° C in a humid atmosphere planted the composition the detonation does not continue at a pressure of 17.6 kg / cm2.

Composition G. The fresh sample planted after 15 minutes of immersion at a pressure of only 10.6 kg / cm2 the detonation does not continue, a satisfactory one Detonation was only achieved at a pressure of 6.1 kg / em2.

Composition H. A fresh sample detonated at one rate of 5640 m per. second after submerging for 15 minutes at a pressure of 17.6 kg / cm2. A sample stored for 1 month at 38 ° C in a humid atmosphere detonated under the same: Conditions with a, speed of 6680 m per second.

The above examples clearly show. the invention Compositions imparted by the relatively small amounts of the resin balloons improved shelf life. Composition A is a typical gelatin dynamite composition, in which so much of the previously used low density ingredients are used is that even at high pressures one achieves the desired reproductive capacity. The storage test clearly shows that ß the reproductive capacity after 1 month However, storage has decreased significantly. The compositions B and C correspond fully of the composition A, but contain the resin balloons, and the Storage test now shows that reproductive capacity is excellent will. Compositions D, E, F and G are typical. for the so-called "ammonia gelatine" dynamites. Composition F is a typical well-known composition, and the fertility test even on a fresh sample shows that the sensitivity after immersion, is unsatisfactory under water under pressure. The awarding of the resin balloons Not only does it increase initial fertility, but this increased sensitivity is retained even after otherwise harmful storage.

Claims (1)

PATENT CLAIM: Dynamic composition containing liquid nitric acid esters and at least one low density component characterized by a Content of at least 0.25 percent by weight, preferably 0.25 to 4%, of one in water and in. Nitroglycerin insoluble, thermosetting, combustible resin in the form of hollow, spherical balloons whose bulk density is less than 0.3 g / ccm and whose Diameter is between 2 and 360 microns.