RU2121471C1 - Explosive composition (and its modification) and method of its manufacture (and its modification) - Google Patents

Abstract

FIELD: explosives. SUBSTANCE: explosive composition applicable as borehole charges in mining industry and construction contains, wt %: variant 1 powdered organic combustible with particle size 0.05-3.25 mm, 1.0-6.0; water or aqueous solution of glycol, 1.0-4.0; perlite sand, 0.05-5.0; liquid petroleum product, 2.5-5.0; granulated ammonium nitrate, the balance; variant 2 powdered organic combustible with particle size 0.05-3.25 mm, 2.0- 5.0; liquid petroleum product, 1.0-5.0; water or aqueous solution of glycol, 0.5-4.0; aluminum silicide or its mixture with ferrosilicon with particle size 0.025-0.150 at ratio (1-3):1, 3.0-9.0; ammonium nitrate, the balance. Preparation procedure includes preliminarily drying organic combustible to moisture content 15-40%, treatment with glycol (if necessary) to form aqueous solution of glycol, which is further mixed with other components. EFFECT: increased physical stability and improved detonation parameters, reduced expenses, and extended resource. 14 cl, 1 tbl

Description

 The invention relates to industrial explosive compositions based on non-explosive ingredients for blasting using the method of borehole charges and the method of their manufacture.

 Explosive formulations (BC) based on non-explosive ingredients are widely used both in Russia (patents NN2021240, 1784620, 1811520, 1811519 and others) and abroad (US patent N 542472, Ukrainian patents NN 94076061, 94128166, naphthenites in Hungary, ammoneks in Germany and others). The main components of these aircraft are ammonium nitrate as an oxidizing agent, wood flour, coal dust, peat, lignin, mineral oils, metal powders, etc. as fuel.

 These aircraft have low sensitivity to mechanical stress, wide availability and low cost of raw materials, with the exception of metal powders, which makes it possible to use them as industrial explosives for blasting on the earth's surface for underground work.

Known explosive composition (USSR patent N 136654, claimed 10.02.60), including granular ammonium nitrate, liquid petroleum and powder fuel in the following ratio, wt%:
Liquid petroleum product in the form of solar, spindle, etc. oil, heated fuel oil, petrolatum, paraffin - 2.0-4.0
Powdered fuel in the form of soot, peat, aluminum powder or explosives - 3.0-5.0
Granular ammonium nitrate with a grain size of 0.5-3.0 mm - The rest,
adopted as a prototype of the declared explosive composition.

 The disadvantages of the composition of the prototype are hygroscopicity, and therefore, the need for hermetic packaging, dusting of aircraft during loading of wells, high cost of aircraft due to the use of expensive finely dispersed metal powders.

 When the aircraft is stored in an unpressurized container under changing atmospheric conditions (humidity, temperature), the surface layers are saturated with moisture, aggregate into particles of various shapes and sizes, which leads to a decrease, and sometimes loss of flowability, a change in the composition and bulk density of the borehole charge along the height of the column charge and, as a consequence, to incompleteness of detonation of the charge.

 An object of the invention was to increase the efficiency of the explosive composition by improving the physical stability and detonation parameters of the aircraft, the conditions of loading wells, reducing costs, expanding the raw material base with an increase in the range and volume of output.

The problem was solved by creating an explosive composition and its variant:
for medium-strength rocks - option 1 - containing granular ammonium nitrate, liquid petroleum, powdered fuel, which additionally includes water or an aqueous solution of glycol and perlite sand, and organic fuel with a particle size of 0.05 - 3.25 is selected as a powdered fuel mm;
for hard rocks - option 2 - containing granular ammonium nitrate, liquid petroleum, powdered fuel, which additionally includes water or an aqueous solution of glycol and perlite sand, and organic fuel with a particle size of 0.05 - 3.25 mm is selected as a powdered fuel and metal fuel - silicon aluminum or its mixture with ferrosilicon with a particle size of 0.025 - 0.150 mm in a ratio of 1: 1 to 3: 1, and the components included in the composition (options 1 and 2) are taken in the following ratio, wt.%:
Option 1
Powdered organic fuel with a particle size of 0.05-3.25 mm - 1.0-6.0
Metallic fuel - siliceous aluminum or its mixture with ferrosilicon with particle sizes of 0.025-0.150 mm in a ratio from 1: 1 to 3: 1 - -
Liquid petroleum product - 2.5-5.0
Water or aqueous glycol solution - 1.0-4.0
Perlite sand - 0.05-5.0
Granular Ammonium Nitrate - Else
Option 2
Powdered organic fuel with a particle size of 0.05-3.25 mm - 2.0-5.0
Metallic fuel - siliceous aluminum or its mixture with ferrosilicon with a particle size of 0.025-0.150 mm in a ratio of 1: 1 to 3: 1 - 3.0-9.0
Liquid petroleum product - 1.0-4.0
Water or aqueous glycol solution - 0.5-4.0
Perlite sand - 0.05-5.0
Granular Ammonium Nitrate - Else
moreover, peat, or lignin, or wood flour or a mixture of them in any ratio is selected as the organic fuel, mineral oils or a mixture of mineral oils such as diesel fuel, or industrial, or instrument, or hydrochloric oil are used as liquid petroleum products, in addition , for a number of purposes, in particular for charging holes with a diameter of about 40 mm, granular ammonium nitrate is chosen such that the content of granules with sizes of 0.5-3.0 mm and 0.05-1.50 mm is from 1: 1 to 5: one.

 The introduction of water in the proposed aircraft and its variant helps to reduce dusting, hygroscopicity; glycol - freezing at sub-zero temperatures, increasing bulk density, completeness of detonation, improving the sanitary and hygienic conditions for the manufacture and use of the proposed aircraft. During the manufacturing process, the capillary-porous structure of organic fuel (peat, lignin) is preserved and the latter performs, along with perlite sand in the aircraft, an additional function of a gas-bearing sensitizing additive, thereby increasing the detonation parameters of the aircraft and the borehole charge on its basis, and improving the environmental conditions for the use of the proposed aircraft.

 The selected granulometric composition of organic (0.05-3.25 mm) and metal (0.025-0.150 mm) fuel, ammonium nitrate ensures uniform distribution of fuel in the oxidizing medium, flowability and high bulk density, constancy of the composition components in volume as during storage, transportation, and when loading wells.

 The use of siliceous aluminum metal or its mixture with ferrosilicon with a particle size of 0.025-0.150 instead of aluminum powder (powder particle size from 0.0007 to 0.007 mm) in option 2 as a metal combustible aluminum reduces the cost, reduces the accumulation of charges of static electricity in the manufacture of aircraft and loading wells while maintaining the completeness of the explosive transformation reaction. The need for two options of the claimed composition is due to a significant difference in the strength of the blasted rocks. For rocks with a strength of up to 10-12 on the M. M. Protodyakonov scale, it is recommended to use the inventive composition according to option 1, including ammonium nitrate, liquid petroleum product, organic fuel, water or an aqueous solution of glycol and perlite sand.

 For blasting on hard rocks (12-20 on the M.P. Protodyakonov scale), the specific completeness of the explosion, and therefore the aircraft’s operability under option 1, is insufficient. It can be increased by including in the composition of the inventive aircraft according to option 1 an additional metallic fuel, which is selected as silicon aluminum or its mixture with ferrosilicon in a ratio of 1: 1 to 3: 1.

 An explosive composition, which in addition to the ingredients of option 1 additionally contains the selected metal fuel, is option 2.

 Liquid petroleum products - mineral oils such as diesel fuel, industrial, instrument, solar, spindle oils, or others, or their mixture have similar thermodynamic characteristics and practically do not affect the energy parameters of the proposed explosive composition and its variant.

 As an oxidizing agent, granular ammonium nitrate with a granule size of 0.5 - 3.0 mm, manufactured by the industry, is selected, and for some purposes a mixture of nitrate with granule sizes of 0.5-3.0 and 0.05-0.5 mm is used in the ratio from 1: 1 to 5: 1, due to which the bulk density increases, the bulk heat of the explosion, the critical diameter of the detonation decreases.

 In both versions of the inventive aircraft, the main technical result is achieved - reducing dusting, freezing in winter conditions, increasing bulk density, constant component composition of the borehole charge along the height of the charge column, completeness of detonation, cost reduction, and for option 2 there is also an additional technical result - increasing efficiency .

 The specified technical result of the invention is also achieved due to the proposed ratio of ingredients and their dispersion, selected from the conditions of a balanced ratio of fuel and oxidizing agent, which ensures optimal values of conversion (oxygen balance), toxic gas content, energy (specific heat of explosion, total volume of gases) and detonation (speed and critical diameter of detonation) parameters of the proposed aircraft according to option 1 and 2.

 A known method of manufacturing industrial aircraft based on granular ammonium nitrate by treating its granules with liquid oil first (oiling), for example, with solar oil and other oil, and then mixing oiled granules of nitrate with powdery combustible material, such as aluminum powder, soot, peat, etc. (USSR patent 136654, declared. 10.02.60), adopted as a prototype for the proposed method of manufacturing aircraft. The disadvantage of this method is the dusting and accumulation of charges of static electricity in the manufacture of aircraft and charging wells, the hygroscopicity of the aircraft when stored in leaky conditions, the heterogeneity of the component composition along the height of the charge column when charging wells.

The proposed manufacturing method is that pre-powdered fuel is dried to a moisture content of 15-40 wt.%, Excluding dusting, and then mixed at a temperature of 20 ± 10 ^o C processed (oiled) liquid petroleum ammonium nitrate with perlite sand (for the composition of option 1 ) or mixed oily ammonium nitrate with perlite sand and powdered metal fuel (for the composition of option 2). To avoid freezing when using sun in winter, organic fuel with a moisture content of 15-40 wt.% Is first treated with glycol to form an aqueous glycol solution, and then mixed at a temperature of 20 ± 10 ^o C with other components of the sun.

When the temperature of mixing the components below 10 ^o C does not provide uniform wetting and distribution of the components of the aircraft.

At temperatures above 30 ^o C deteriorate sanitary conditions of production due to the increased volatility of the liquid oil.

 The components are mixed in mixers used in the production of ammonium nitrate explosives.

 The proposed method for the production of ammonium nitrate explosives eliminates dusting, improves the sanitary and hygienic conditions of production and use of aircraft, improves production safety, ensures uniform distribution of components along the height of the charge column when loading wells, and detonation completeness.

 The proposed method can be applied for the production of aircraft both in the factory and at the places of use of explosives in continuous and batch production.

The technological process of production includes the following phases:
drying of organic fuel to a moisture content of 15-40 wt%; processing (oiling) of ammonium nitrate granules with liquid oil to uniformly wet the surface of the granules; mixing at a temperature of 20 ± 10 ^o C oiled ammonium nitrate with organic combustible, perlite sand to ensure uniform distribution of powder components (organic fuel and perlite sand) on the surface of the granules of ammonium nitrate in the production of aircraft version 1;
or
mixing at a temperature of 20 ± 10 ^o C oiled ammonium nitrate with organic fuel, perlite sand, metal fuel with a uniform distribution of powder components (organic and metal combustible, perlite sand) on the surface of the granules of ammonium nitrate in the production of aircraft version 2.

 When using BC at sub-zero temperatures after drying the organic fuel, it is treated with glycol to form an aqueous glycol solution.

 For the manufacture of aircraft designed for loading holes with a diameter of about 40 mm, 15-50 wt.% Ammonium nitrate is additionally crushed to a particle size of 0.05-1.50 mm and mixed into granules of 0.5-3.0 mm. Grinding can be done both before and after oiling with oil.

 For the production of aircraft by the proposed method, factory-made ammonium nitrate is used with a particle size of 0.5-30 mm in accordance with the regulatory and technical documentation, powdered organic fuel in the form of peat, or lignin, or wood flour, or a mixture thereof with a particle size of 0, 05-3.25 mm, siliceous aluminum or a mixture thereof with ferrosilicon with a particle size of 0.025-0.150 mm, liquid petroleum product, perlite sand.

 The table shows examples of the proposed aircraft.

 The water-oil film formed by mixing the components of the aircraft ensures a uniform distribution of fuel in the oxidizing medium, preserves the capillary-porous structure of the powdered organic fuel, thereby providing additional sensitization of the aircraft, while improving the sanitary and hygienic conditions for the production of aircraft and charging wells and holes, achieving a constant composition, high composition detonation parameters, completeness of detonation at lower values of the critical diameter of detonation in avg Skills with a prototype. The cost of the proposed aircraft is 30-40% lower in comparison with the prototype.

The manufacture of the compounds was carried out according to the above process. The mixing temperature ranged from 10-30 ^o C.

 The manufactured aircraft according to options 1 and 2 had a homogeneous composition, they maintained flowability during transportation, storage and loading of wells.

The proposed aircraft for option 1 and 2 are made and tested with positive results when blasting rocks of various strengths in wells with a diameter of 105-256 mm and holes with a diameter of 40 mm at temperatures from -40 to 50 ^o C.

Claims (12)

1. An explosive composition, including granular ammonium nitrate, liquid petroleum product and powdered fuel, characterized in that it additionally contains water or an aqueous solution of glycol, perlite sand, and as a powdered fuel - organic fuel with a particle size of 0.05 - 3.25 mm in the following ratio of components, wt.%:
Liquid oil - 2.5 - 5.0
Powdered organic fuel with a particle size of 0.05 - 3.25 mm - 1.0 - 6.0
Water or aqueous glycol solution - 1.0 - 4.0
Perlite sand - 0.05 - 5.0
Granular Ammonium Nitrate - Else
2. The composition according to claim 1, characterized in that the liquid oil contains mineral oil or a mixture of mineral oils.  3. The composition according to claim 1, characterized in that as a powdered organic fuel contains peat, or lignin, or wood flour, or a mixture thereof in any ratio.  4. The composition according to claim 1, characterized in that it contains ammonium nitrate with granule sizes of 0.5 - 3.0 mm and 0.05 - 1.5 mm in a ratio of 1: 1 to 5: 1. 5. Explosive composition, including granular ammonium nitrate, liquid petroleum product and powdered fuel, characterized in that it additionally contains water or an aqueous solution of glycol, perlite sand, as a powdered fuel - organic fuel with a particle size of 0.05 - 3.25 and metal fuel - silicon aluminum or its mixture with ferrosilicon with particle sizes of 0.025 - 0.150 mm in a ratio of 1: 1 to 3: 1 in the following ratio of components, wt.%:
Liquid oil - 1.0 - 4.0
Powdered organic fuel with a particle size of 0.05 - 3.25 mm - 2.0 - 5.0
Water or aqueous glycol solution - 0.5 - 4.0
Siliceous aluminum or a mixture thereof with ferrosilicon with a particle size of 0.025 ... 0.150 mm with a ratio of 1: 1 to 3: 1 - 3.0 - 9.0
Granular Ammonium Nitrate - Else
6. The composition according to claim 5, characterized in that the liquid oil contains mineral oil or a mixture of mineral oils.  7. The composition according to claim 5, characterized in that as a powdered organic fuel contains peat or lignin, or wood flour, or a mixture thereof in any ratio.  8. The composition according to claim 5, characterized in that it contains ammonium nitrate with granule sizes of 0.5 - 3.0 mm and 0.05 - 1.5 mm in a ratio of 1: 1 to 5: 1. 9. A method of manufacturing an explosive composition, including the processing of granular ammonium nitrate by oiling it with liquid oil and mixing with a powder fuel, characterized in that the organic fuel is used as a powder fuel, which is pre-dried to a moisture content of 15-40 wt.%, And then a temperature of 20 ± 10 ^o C mixed with oily granulated ammonium nitrate and perlite sand.  10. The method according to claim 9, characterized in that the ammonium nitrate is preliminarily crushed to a granule size of 0.05-1.5 mm, mixed with granules of a size of 0.5-3.0 mm in a ratio of 1: 1 to 1: 5.  11. The method according to claim 9, characterized in that for using the explosive composition at sub-zero temperatures after drying the organic fuel, it is treated with glycol to form an aqueous glycol solution. 12. A method of manufacturing an explosive composition, including the processing of granular ammonium nitrate by oiling it with liquid oil and mixing with a powder fuel, characterized in that the powder fuel uses organic and metal fuel, and the organic fuel is pre-dried to a moisture content of 15-40 wt. %, and then at a temperature of 20 ± 10 ^o C is mixed with oily granulated ammonium nitrate, perlite sand and metallic fuel.  13. The method according to p. 12, characterized in that pre-ammonium nitrate is crushed to a particle size of 0.05 to 1.5 mm, and mixed with granules of 0.5 to 3.0 mm in a ratio of 1: 1 to 1: 5 .  14. The method according to p. 12, characterized in that for using the explosive composition at sub-zero temperatures after drying the organic fuel it is treated with glycol to form an aqueous glycol solution.

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