UA148470U - METHOD OF OBTAINING EMULSION EXPLOSIVE SUBSTANCE - Google Patents

Abstract

A method of producing an emulsion explosive without the formation of toxic nitrogen oxides includes obtaining a water-in-oil emulsion by emulsifying the fuel phase and an aqueous solution of an oxidant containing inorganic nitrates and acid, and then filling the resulting emulsion by mixing it with a gas-generating solution. sodium and gas regulator. Sulfamic acid is used as the acid in the oxidant solution, and calcium chloride is used as the gas formation regulator in the gas-generating solution.

Description

The utility model belongs to the method of obtaining industrial emulsion explosives and can be used in the mining industry for the destruction of rocks.

Emulsion explosives (EBU) are widely used in Ukraine, as they have increased detonation parameters, are safe and non-toxic compared to explosive materials that contain TNT. Unlike standard TNT explosives, EVRs are formed directly at the site of application when mixing the emulsion composition and the sensitizing additive.

Emulsion compositions are reverse emulsions of an aqueous solution of the oxidant - ammonium nitrate or its mixture with calcium or sodium nitrates in the continuous phase of the fuel component (reductant).

Emulsion compositions acquire detonation properties only after the introduction of sensitizers that reduce the density of the emulsion. Gas-generating additives (GGD) are used as sensitizers for bulk EWRs, whose contact with the emulsion composition ensures saturation of the emulsion volume with gas inclusions.

A generally accepted way of obtaining EVR is mixing the emulsion composition with an aqueous solution of sodium nitrite. It is considered |Kuprin V.P., Kovalenko I.L. Development and implementation of emulsion explosives in quarries of Ukraine. - Dnipropetrovsk: DVNOZ

UDHTU, 2012. - p. 1121, that during the reaction of sodium nitrite with ammonium nitrate in the oxidation phase of the emulsion, ammonium nitrite is formed, which decomposes with the release of nitrogen bubbles:

Mamo2-MNAMOz-Mamoz--MNAMO»

MNAMO»2-M2a2 NO.

It is significant that "nitrite" gas generation occurs only in an acidic environment. In such conditions, together with the above reaction, the interaction of sodium nitrite with nitric acid, which is always present in the acidic environment of the ammonium nitrate solution, will produce unstable nitric acid, which decomposes with the formation of nitrogen oxides:

Mmamo2-NMOz-MamoOz-NMO" 2NMO2-MO-MO"--H2O, which are highly toxic substances (2nd class of danger).

З A known method of obtaining an emulsion explosive without the formation of toxic nitrogen oxides, which includes obtaining a "water-in-oil" type emulsion by emulsifying the fuel phase and an aqueous solution of an oxidizer containing ammonium nitrate or a mixture of ammonium and calcium nitrates, and acid, and subsequent gas filling of the obtained emulsion by mixing it with a gas-generating solution containing sodium nitrite and a gas formation regulator | see UMO 03/055830, IPC СОб6В 47/14, publ. 10.07.2003|, selected as a prototype. In this method, an aqueous solution of an oxidizing agent with a hydrogen pH value of 0 to 3 is used, which contains one or more organic acids, preferably citric, and urea is used as a regulator of gas formation in the gas-generating solution.

The implementation of this method made it possible to ensure rapid gas generation of EWR without the formation of toxic nitrogen oxides (NOx).

The authors of the well-known technical solution found that lowering the pH with the use of an organic acid practically eliminates the formation of MOX during gas generation, if urea is used as a gas generation accelerator.

However, it is known that carbamide affects the detonation parameters of EVR, significantly reducing the detonation speed |(Kolganov E.V., Sosnin V.A. Zmulsionnyue promyishlennie vryivchate substance. Book 1. Compositions and properties. - Dzerzhinsk: GOSNYIY "Krystal", 2009 - 592 s.|.At the same time, the use of EVR with an increased detonation speed (025.0 km/s) is necessary for the destruction of rocks in iron ore quarries.

It is known that the speed of EVR detonation primarily depends on the dispersion of oxidizer particles in the fuel phase. Achieving high dispersion (1.5-2.0 μm) and ensuring the stability and water resistance of the emulsion over time is possible only with the use of effective polymer emulsifiers. It has been established that the high speed and stability of EVR detonation is achieved not only by increasing the dispersion of emulsions, but also by reducing the size of gas bubbles (S.A. Horinov, Initiation and detonation of emulsion explosive substances // Edited by Academician of the Russian Academy of Sciences, V.V. Adushkina - Yoshkar-Ola: "String", 2020. - pp. 109-1111.

The useful model is based on the task of improving the method of obtaining an emulsion explosive without the formation of toxic nitrogen oxides during sensitization and increasing the speed of its detonation.

The problem is solved by the fact that in the method of obtaining an emulsion explosive substance without the formation of toxic nitrogen oxides, which includes obtaining a "water-in-oil" type emulsion by emulsifying the fuel phase and an aqueous solution of the oxidant, which contains inorganic nitrates and acid, and subsequent gas filling of the resulting emulsion by mixing it with a gas-generating solution containing sodium nitrite and a gas-forming regulator, according to a useful model, sulfamic acid is used as an acid in the oxidizer solution, and calcium chloride is used as a gas-forming regulator in the gas-generating solution.

At the same time, the oxidizer solution contains 0.15-0.2 9o sulfamic acid, the gas-generating solution contains 10 95 sodium nitrite and 15 95 calcium chloride, and when obtaining a "water-in-oil" emulsion, the emulsifier "I ibgi2o!" or "Emulsifier universal brand "PEM", or "Stabilizer of technical STEO emulsions", and 30 95 of granular or porous ammonium nitrate is added to the emulsion explosive.

It was found that unlike other acids (acetic, nitric, citric) used in nitrite gas generation, sulfamic acid at concentrations an order of magnitude lower compared to citric and other acids ensures complete conversion of nitrites into nitrogen without the formation of MOx oxides:

MN»ZOzZNaANMO»-M2--NgO ZhNgBoh.

Studies have shown that when 10 95 aqueous solution of sodium nitrite and 15 95 calcium chloride are introduced, the size of nitrogen bubbles that are formed when GGD comes into contact with the emulsion decreases by 2-3 times, which leads to an increase in the number of "hot spots" at the initiation of EVR and, accordingly , to increase the sensitivity and speed of detonation of the explosive substance.

Thus, due to the use of sulfamic acid as an oxidant and calcium chloride as a component of GGD based on sodium nitrite, the production of an emulsion explosive is ensured not only without the formation of toxic nitrogen oxides, but also with an increased detonation speed.

The method of obtaining the claimed emulsion explosive is carried out as follows.

The emulsifier is dissolved in the petroleum product at a temperature of 40:10 "C, thereby preparing the fuel phase for obtaining an emulsion.

In a reactor equipped with a heat exchanger and a stirrer, the oxidizer solution is prepared by

From successive dissolution in hot water at 90-100 "С of ammonium nitrate, or a mixture of calcium and ammonium nitrate, add the prescription amount of sulfamic acid.

Emulsion production is carried out in devices - mixers of the dynamic and/or static type with advance feeding of the fuel phase into the mixer. The components are actively mixed to obtain a homogeneous emulsion.

To obtain EVR, a gas-generating additive is introduced into the obtained emulsion, which is a 10 95 aqueous solution of sodium nitrite, which additionally contains 15 95 wt. calcium chloride.

In order to confirm the influence of sulfamic acid and calcium chloride on the processes of sensitization of EVR and its detonation parameters, various compositions of EVR were prepared and their parameters were investigated, which are shown in the table.

Studies have shown that in order to obtain a highly dispersed emulsion, it is necessary to use effective emulsifiers of type I ibgi2oi 2820, or "Universal emulsifier of the brand "PEM" (TU U 20.4-19436711-010:2019), or "Emulsion stabilizer of the technical brand "STEO" (TU U 20.1 -19436711-009-2016).

The concentration of nitrogen oxides was measured using a Dozor-S-M gas analyzer-signaler (NPO "Orion", Kharkiv).

The size of the gas bubbles was measured using a Vgezzeg Juisiyh microscope with a BISETA OSMO5 05100 KRA 5.1 MRX digital eyepiece.

The detonation speed was determined according to DSTU EM 13631-14:2005 "Explosive explosive substances" part 14.

The data shown in the table indicate that the introduction of sulfamic acid into the oxidizer provides sensitization of the EVR without the formation of toxic nitrogen oxides, and the use of calcium chloride as a regulator of gas formation increases the detonation rate of the EVR.

It can be seen from the given data that, regardless of the composition of nitrates in the oxidant solution, the addition of 0.15-0.20 96 wt. of sulfamic acid completely eliminates the formation of toxic nitrogen oxides during EVR sensitization (formulations 2-3 and 5-6).

To increase the heat of the explosion, up to 30 95 of granular or porous ammonium nitrate can be added to the above EVR compositions.

Table

Compositions of emulsion explosives and their indicators

Components, mass 9 Nearest warehouse numbers t yanalog | 1 | 2 | with | 4 | 5 | 6

Oxidant solution:

Ammonium nitrate 55.0 83.5 83.45 79.3 72.7 70.5 58.9

Calcium nitrate 30.0 - - - 10.9 10.85 221

Water 13.0 16.4 16.4 20.5 16.3 18.5 18.8

Citric acid 2.0 - - - - - -

Sulfamic acid - 0.10 0.15 0.2 0.10 0.15 0.2 95 of the content in EVR

Fuel phase:

Emulsifier 25.0 20.0 20.0 15.5 17.0 17.0 12.0

Petroleum product 75.0 80.0 80.0 84.5 83.0 83.0 88.0 95 content in EVR 60 1 70 | 70 | 65 | 75 | 75 | 85

Gas generating solution:

Sodium nitrite 15.0 10.0 10.0 10.0 10.0 10.0 10.0

Urea 20.0 - - - - - -

Water 65.0 75.0 75.0 75.0 75.0 75.0 75.0

Calcium chloride - 15.0 15.0 15.0 15.0 15.0 15.0 95 of the content in EVR

Moss concentration, (mg/m)| 04 | 02 | 0 | 0 | 0 | 0 | about blisters, μm

Detonation speed, m/s 5050 5500 5800 5700 5450 5600 5500

Claims (6)

USEFUL MODEL FORMULA 1. The method of obtaining an emulsion explosive without the formation of toxic nitrogen oxides, which includes obtaining a "water-in-oil" type emulsion by emulsifying the fuel phase and an aqueous solution of an oxidizer that contains inorganic nitrates and acid, and subsequent gas filling of the obtained emulsion by mixing it with a gas-generating solution , which contains sodium nitrite and a gas formation regulator, which differs in that sulfamic acid is used as an acid in the oxidizer solution, and calcium chloride is used as a gas formation regulator in the gas-generating solution. 2. The method according to claim 1, which differs in that the oxidant solution contains 0.15-0.2 95 sulfamic acid. C. The method according to claim 1, which differs in that the gas-generating solution contains 10 95 sodium nitrite. 4. The method according to claim 1, which differs in that the gas-generating solution contains 15 95 calcium chloride. 5. The method according to claim 1, which differs in that when obtaining an emulsion of the "water in oil" type, the emulsifier "I ybyloi" or "Universal emulsifier of the "PEM" brand, or "Stabilizer of technical STEO emulsions" is used. 6. The method according to claim 1, which differs in that 30 95 of granular or porous ammonium nitrate is added to the emulsion explosive.