UA58528C2 - A packaged explosive emulsion - Google Patents

Abstract

A packaged explosive emulsion of water-oil type is sensibilized by dispersed gas and contains ammonium nitrate (60-70%), sodium nitrate (8-14%), water (4-7%), fuel based on hydrocarbons (0.5-5%), emulsifier (0,5-5%), aluminium (12-18%). Sum of ammonium nitrate and sodium nitrate contents is between 70% and 80%, sum of ammonium nitrate, sodium nitrate, water, fuel based on hydrocarbons, emulsifier and aluminium contents is between 95% and 100%. The explosive emulsion is safe in use and production, and has energy and power of dynamites, it is especially able for blasting the solid rocks.

Description

Description of the invention

This invention relates to general questions of the application of industrial explosives for civil needs.

The invention relates to the latest cartridged explosive emulsions, which are suitable, in particular, for planting hard rocks in quarries or on factory sites.

Cartridge explosive emulsions of the water-oil type are well known to those skilled in the art.

They include: a dispersed aqueous phase in the form of droplets of an aqueous solution of inorganic oxidizing salts, 70 a homogeneous organic phase immiscible with water, in which the above-mentioned droplets are dispersed, an emulsifier that forms an emulsion of aqueous droplets in the entire volume of a homogeneous organic phase, a dispersed gas phase that is uniformly dispersed in the emulsion and that increases the sensitivity of the emulsion to ignition, each bubble of dispersed gas acts as a superheat area.

Compared with ordinary dynamite, which contains from 2595 to 4595 of nitroglycerin, the above-mentioned explosive 12 emulsions are safe to use, and their manufacture is markedly improved. On the other hand, they are noticeably less powerful and emit less explosive energy.

Specialists in this field have long been looking for explosive emulsions of the above type, which would have the inherent safety and sensitivity to ignition of known cartridge explosive emulsions and the power of dynamite, that is, the detonation speed in the region of b00Ω/s, measured in a volume limited to a diameter of 8Ω, at of total energy measured under water, which exceeds approximately 1100Ocal/g.

It is well known that in order to increase the speed of detonation of explosive substances, their density is increased. However, in the case of cartridged explosive emulsions sensitized by the dispersed gas phase, an increase in density entails a decrease in the content of the gas phase in the volume, and therefore reduces the sensitivity to ignition.

This reduction in sensitivity can be compensated for by introducing into the compositions sensitizing molecules, such as hydrazine nitrite and organic nitrates, in particular amine nitrates, for example methylamine nitrate, or Ge) introducing, alternatively, reaction catalysts such as copper chloride, or and such even more reactive oxidizers, such as chlorates or perchlorates.

However, the use of such stabilizing molecules, catalysts and/or chemically active oxidizing agents entails a significant risk of unpredictable pyrotechnic events. This is because organic nitrates, cochlorates, and perchlorates are particularly dangerous to handle, hydrazine nitrate is unstable, and c metal catalysts can react with ammonium nitrate, an inorganic oxidizing salt that is practically always used in formulations, alone or in a mixture with other oxidizing salts. at

For example, EP 598 115 describes powerful explosive emulsions based on ammonium nitrate, containing amine nitrate and/or hydrazine nitrate as a sensitizer. 3o US Patent 4,371,408 describes explosive emulsions based on ammonium nitrate and sodium nitrate sensitized with amine nitrate containing SiCSi as a detonation catalyst.

A well-known practical measure is also the introduction of aluminum into explosive emulsions in order to increase their energy.

However, in practice, the increase in aluminum content is limited by the fact that the energy yield, which is the ratio between the measured energy and the theoretically calculated energy, is greatly reduced in this case. With 50 In addition, it is known that with an increase in the aluminum content, the detonation speed decreases due to a decrease in the mass content of gaseous products in the decomposition products.

From" On the basis of this theory and these experimental data, it seems implausible to one of ordinary skill in the art to obtain emulsions having all the desired properties and features noted above.

However, this prejudice was overcome.

It turned out, in particular, unexpectedly, that by combining the weight content of ammonium nitrate and sodium nitrate within specific enough limits, in the absence of other inorganic salts, sensitizing molecules, such as

Ge | organic nitrates or hydrazine nitrate, and metal catalysts, as well as by carefully choosing the nature and weight content of other components, especially the water and aluminum content, it is possible to obtain explosive and emulsions that have sensitivity to ignition and safety of use and production, characteristic of ka 20 standard cartridge explosive emulsions, and at the same time they have the performance characteristics of ordinary dynamite, that is, a detonation speed in the region of 6000 m/s, measured in a volume limited by a diameter of 8 Ohm, and with a total energy measured under water of more than 11OOcal /g, which can even exceed 12OOcal/g, with an energy output exceeding 8095.

Thus, the subject of the present invention is the latest cartridged explosive emulsions of the water-oil type, which are sensitized by the dispersed gas phase and which contain ammonium nitrate, sodium nitrate, water, fuel on

GF) based on hydrocarbons, emulsifier and aluminum.

The characteristic features of the latest explosive emulsions are: o weight content of ammonium nitrate - between 6095 and 70965, weight content of sodium nitrate - between 895 and 1496, weight content of water - between 495 and 795, weight content of fuel based on hydrocarbons - between 195 and 495, the weight content of the emulsifier is between 0.595 and 495, the weight content of aluminum is between 1295 and 1890, the sum of the weight contents of ammonium nitrate and sodium nitrate is between 7095 and 8090, because the sum of the weight contents of ammonium nitrate, sodium nitrate, water, hydrocarbon-based fuel, emulsifier and aluminum is between 9595 and 10095, preferably between 9890 and 100905, and even better - between 9995 and 100905.

The above weight contents are shown relative to the sensitized explosive emulsion, and it should be understood that limits are included in the consideration.

The latest explosive emulsions proposed according to the invention, in particular, do not contain chlorates and perchlorates, for example, ammonium chlorates and perchlorates, alkali metals or alkaline earth metals, do not have sensitizing molecules such as organic nitrates; for example, alkylamine nitrates and alkanolamine nitrates, or such as hydrazine nitrates, such as hydrazine nitrate and methylhydrazine nitrate, and do not have metal reaction catalysts such as copper chloride. 70 In addition, the hydrocarbon-based fuel can be a mixture of several types of hydrocarbon-based fuel, and the emulsifier can be a mixture of several emulsifiers.

Hydrocarbon-based fuels can be aliphatic, cycloaliphatic, or aromatic, as well as saturated or unsaturated. It is possible to note, for example, toluene, xylenes, white spirit, kerosene, fuel oil, paraffins, oils, in particular, paraffinic oils or naphthenic oils, fatty acids and their derivatives, waxes and their mixtures, that is, any mixture of at least two of the mentioned components .

Fuel based on hydrocarbons is selected, preferably, from the group consisting of oils, waxes and paraffins, as well as their mixtures.

The emulsifier can be any emulsifier well known in the art to contribute to the physical stability of water-in-oil emulsions by reducing the interfacial tension between the two phases of the emulsion.

The emulsifier is chosen mainly from the group, which includes polymer emulsifiers that have both hydrophilic and hydrophobic chains, for example, derivatives of polyisobutylene and derivatives of succinic anhydride, amines, especially those containing from 12 to 24 carbon atoms, fatty acid esters, such as sorbitan monooleate, sorbitan laurate, sorbitan pdlmitate and sorbitan stearate, alkylaryl esters of sulfonic acids and mixtures thereof. high school

Aluminum in the context of this invention is used finely chopped, preferably in the form of powder.

The size of its particles generally ranges from 0.1 mm to 250 mm, and preferably between 0.5 mm and 150 mm. (8)

Explosive emulsions according to the invention are sensitized by the dispersed gas phase according to a method well known to specialists in the field.

Among the most well-known methods of introducing the gas phase into explosive emulsions, we can note mechanical mixing, on-site gas release with the help of chemical reagents, and introduction of porous material containing closed cells, for example, glass or plastic microspherical gas containers, polystyrene foam grains, or ash dust. It is also possible to combine different methods, for example, simultaneously using chemical reagents and microspheres.

According to the present invention, a method of on-site gas release using chemical reagents is preferred, in particular, using nitrites, such as sodium nitrite, which, upon reaction with ammonium ions and ammonium nitrate, immediately begins to release nitrogen. This reaction can be accelerated by an increase in temperature and/or a catalyst such as urea, thiourea, or thiocyanate.

In a most preferred embodiment of the invention, the explosive emulsions according to the invention contain from 13 to 17 volume percent of the dispersed gas phase, and preferably from 14 to 16 volume percent. "

According to one of the preferred embodiments of the invention, the sum of the weight content of ammonium nitrate and sodium nitrate is between 7395 and 7795, and preferably between 74905 and 76905. According to another preferred embodiment of the invention, the weight content of ammonium nitrate is between 6195 and 6790, preferably between 62905 and 6595.

According to yet another preferred embodiment of the invention, the water content by weight is between 4.590 and 6.596, more preferably between 5905 and a bean. c According to another preferred embodiment of the invention, the weight content of aluminum is between 1395 and 1790, preferably between 13.595 and 16.595, and even more preferably between 14905 and 16905. c According to another preferred embodiment of the invention , the weight content of the emulsifier is between 1.595 and 495, and preferably between 295 and 3.595.

According to yet another preferred embodiment of the invention, the weight content of the hydrocarbon-based fuel is between 0.790 and 495, preferably between 0.895 and 395, and even more preferably between 195 and 2905. Also, the density of explosive emulsions according to according to the invention is preferably between 1.26 and 1.40, preferably between 1.28 and 1.37, their detonation speed, measured in a volume limited by a diameter of 80 mm, is from 550O0m/s to 630Ω/s, in in the best option from 575Ω/s to bZOOOm/s, and their real total energy, determined under water, is from 1100cal/day to 1400cal/g, in the best option from 1200Ocal/day to 14O0Ocal/g.

Explosive emulsions according to the invention can be obtained by analogy with any process already known

F) for obtaining explosive water-oil emulsions, which are sensitized by the dispersed gas phase and contain ammonium nitrate, sodium nitrate, water, hydrocarbon-based fuel, emulsifier and aluminum.

In the first stage, for example, it is possible to prepare: 1) an aqueous phase by dissolving ammonium nitrate and sodium nitrate in water at a temperature, for example, between 1007 and 105°C, in a tank equipped with a heating system and a stirring system.

In the case of chemical gas formation, at this stage, the above-mentioned reaction catalyst, such as urea, thiourea or thiocyanate, can be added to the gas phase in optimal quantities. 2) a fatty phase consisting of a hydrocarbon-based fuel and, of course, an emulsifier, by mixing the components together at a temperature, for example, in the region of 95"C in a tank equipped with a heating system and a mixing system.

At this stage, the emulsifier can also not be introduced into the hydrocarbon-based fuel.

Then, in the second stage, a water-oil emulsion is prepared, continuously or periodically.

According to the batch method of preparation, after introducing into the mixer the necessary quantities of the water phase, the fat phase and the emulsifier, if it was not introduced into the fat phase, it is possible to obtain an emulsion using a turbo mixer for this purpose, and simultaneously homogenize it, for example, using a paddle mixer in in the form of a clover leaf.

According to the continuous method of preparation, both phases and the emulsifier, if it was not introduced into the fat phase, are pumped with the help of dosing pumps into the supply pipelines of the emulsifying machine. 70 After that, in the third stage, various activating additives are introduced into the obtained emulsion, that is, aluminum, a chemical source of gas and/or microspheres.

According to the batch method of preparing aluminum, the microspheres and/or a chemical gas source are introduced into the emulsion, preferably by mixing in a mixer used to prepare the emulsion or in a mixer with a planetary mixing system.

According to the continuous method of preparation, activating additives are introduced, preferably, continuously, for example, with the help of an auger into the mixing device, into which the water-oil emulsion from the emulsifying machine is also poured.

Next, the sensitized explosive emulsions prepared in this way are placed, after the first cooling, which is optional, manually or automatically, in shells, for example, paper or plastic, with the help of 2o cartridge-equipment equipment, which is well known to those skilled in the art.

The resulting cartridges are then subjected to general cooling, for example with cold water or cold air, depending on the nature of the shell, to stabilize the resulting final emulsion.

The following non-limiting examples illustrate the invention and the advantages it provides.

Examples 1 and 2: Explosive emulsions according to the invention of Art

Below is the weight composition of the prepared explosive emulsions: o 111 devices

IC c)

Example 1 a) Preparation of the aqueous phase 74.3 parts by weight of ammonium nitrate, 13.8 parts by weight of sodium nitrate and 0.04 parts by weight of thiourea are dissolved at a temperature from 1007" to 105"C in 6.6 parts by weight of water in a tank equipped « 70 bistem heating and mixing system. from с b) Preparation of the fatty phase A mixture consisting of: - 3.7 parts by weight of an emulsifier, which is a mixture with a ratio of 40/60 by weight, respectively, sorbitan:z» monooleate and a polymer, which includes polyisobutylene chains with hydrophilic the ends connected through the functions of succinic anhydride - 1.6 parts by weight of fuel based on hydrocarbons, which is a mixture with a ratio of 10/35/20/35 by weight, respectively, of naphthenic mineral oil with an ignition temperature above 100"7C, solid paraffin with a melting point above 50"C, liquid paraffin with an ignition temperature above 1507C and microcrystalline wax with a melting point above 50"7C are homogenized at 95"C in another tank, which is also equipped with a heating system and a mixing system. зо в)п its churning of the emulsion with the addition of activating additives со The aqueous phase a) and fatty phase b) are subsequently loaded into the mixer, where the emulsion is prepared with the help of a turbomixer while simultaneously homogenizing the mixture with the help of a mixer with blades in the form of a clover leaf. The temperature in the shifter is maintained by the process between 1057 and 11076.

After obtaining a homogeneous stable emulsion, 17.7 parts by weight of aluminum powder with a particle size of 0 - 150 µm (average diameter of the order of 8 µm) is added to the mixer, while stirring and maintaining (F. temperature, after which, immediately before the stage of laying in the cartridge, 0, 09 parts by weight of sodium nitrate. d) Placing explosive emulsion in cartridges The explosive emulsion obtained at stage c), whose temperature is maintained, is then placed in cartridges, which are plastic shells, which are then clamped on both sides so as to obtain approximately cylindrical cartridges with a length of, for example, about 32 mm and a diameter of about 8 mm.

The mass of the explosive emulsion that is loaded into each shell is determined by the obvious parameters: the volume of the required cartridge, the density of the explosive emulsion, which is measured before loading into the cartridge and before d5 addition of sodium nitrite, and the desired volume content of the gas phase (approximately 15905).

When the explosive emulsion embedded in the shell occupies the entire volume of the cartridge, the volumetric content of the gas phase is brought to the desired level, after which the chemical reaction of nitrogen formation is stopped by a sharp decrease in the temperature of the emulsion, which is easily achieved by spraying cold water on the cartridges.

Example 2

The process is carried out as in Example 1, but with the following differences: a) Preparation of the aqueous phase

74.9 parts by weight of ammonium nitrate (instead of 74.3), 13.9 parts by weight of sodium nitrate (instead of 13.8) and 6.7 parts by weight of water (instead of 6.6) are used. b) Preparation of fatty phase 70 3.2 parts by weight of emulsifier (instead of 3.7) and 1.3 parts by weight of fuel based on hydrocarbons (instead of 1.6) are used.

The physical and detonation characteristics of explosive emulsions, which were obtained by conventional methods well known to specialists, are as follows:

I nnia s o

Claims (9)

The formula of the invention 1. Cartridge explosive emulsion of the water-oil type, which is sensitized by a dispersed gas phase and contains ammonium nitrate, sodium nitrate, water, hydrocarbon-based fuel, emulsifier and aluminum, which differs in that the ammonium nitrate content by weight is from 6095 to 70905 , the weight content of sodium nitrate is from 895 to 14965, the weight content of water is from 495 to 790, (ge) the weight content of hydrocarbon-based fuel is from 0.595 to 590, the weight content of emulsifier is from 0.595 to 5905, the weight content of aluminum is from 1295 to 1895, the sum of the weight contents of ammonium nitrate and sodium nitrate is from 7095 to 8090, the sum of the weight contents of ammonium nitrate, sodium nitrate, water, hydrocarbon-based fuel, emulsifier and aluminum is from 9595 to 100905. 2. Cartridge explosive emulsion according to claim 1, which differs in that the weight content of water is from 595 to s bob. :with" 3. Cartridge explosive emulsion according to claims 1 or 2, which differs in that the weight content of aluminum is from 13.595 to 16.595. 4. Cartridge explosive emulsion according to claim 1, which differs in that the sum of the weight contents of ammonium nitrate and sl 395 of sodium nitrate is from 73905 to 77905. 5. Cartridge explosive emulsion according to claim 1, which differs in that its density is from 1.26 to 1.40. (uh) 6. Cartridge explosive emulsion according to claim 1, which differs in that its detonation speed, measured in a small volume limited by a diameter of 80 mm, is from 5500 m/s to 6300 m/s. 7. The cartridge explosive emulsion according to claim 1, which is characterized by the fact that its real total energy, determined by ko 50 under water, is from 1100 cal/g to 1400 cal/g. co 8. Cartridge explosive emulsion according to claim 1, which differs in that the volume content of the dispersed gas phase in it is from 1395 to 17905. 9. Cartridge explosive emulsion according to claim 1, which is characterized by the fact that the hydrocarbon-based fuel is selected from the group consisting of oils, waxes, paraffins and their mixtures. 59 10. Cartridge explosive emulsion according to claim 1, which is characterized by the fact that the emulsifier is selected from the group consisting of GF) which includes amines, fatty acid esters, alkylaryl esters of sulfonic acid, polymers containing hydrophilic and hydrophobic chains at the same time as GF, and their mixtures . Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated circuits", 2003, M 8, 15.08.2003. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. b5