RU2663037C2 - Composition of the simplest explosive and the method of its implementation - Google Patents

Abstract

FIELD: blasting operations.SUBSTANCE: invention relates to explosive work, namely, the simplest explosive. Composition includes an oxidizing agent in the form of granular ammonium nitrate and powder material and fuel in the form of a liquid and a solid phase. Ratio of the liquid and solid phases of the fuel is determined on the basis of the parity contribution to the overall oxygen balance of the fuel, while ensuring the zero oxygen balance of the simplest explosive. As the powder material contains ground ammonium nitrate or nitrates of metals of alkali group, as a liquid phase of fuel, oil products are used, and as the solid phase coal powder, coke breeze or rubber crumb of fractional composition – 0.5+0.063 mm are used with the coefficient of anisodiametry of the shape of particles 1–6. Composition is obtained by mixing the components. Composition is intended for production at stationary points of manufacture of granulated industrial explosives and in mixing-charging machines.EFFECT: invention is aimed at ensuring the completeness of energy release in the explosive transformation of the simplest explosive and increasing the physical stability and detonation ability of explosives.9 cl, 1 tbl

Description

The invention relates to blasting and can be used to increase the efficiency of rock blasting in physico-technical and physico-chemical geotechnology. The composition is intended for production at stationary points for the production of granular industrial explosives and in mixing and charging machines.

Known explosive composition (mixed solid rocket fuel), consisting of an oxidizing agent (ammonium perchlorate), a binder-fuel (polyurethanes or hydrocarbon rubbers), heat-conducting additives (aluminum) [Introduction to the technology of energy-saturated materials. 2nd ed. (D.I. Dementieva, I.S. Kononov) - 2009].

The disadvantage of these compositions is the high toxicity of the explosion products, which have a harmful effect on the environment.

The known composition of the explosive, including granular ammonium nitrate, diesel fuel, coal powder, as coal powder, it contains brown coal and additionally ammonium sulfate [RF Patent No. 2005705 M. Cl. C06B 31/28 from 12/27/1991 (prototype)].

The disadvantages of this composition is the complexity and complexity of the manufacturing process, because Numerous technological operations are required, for example, such as impregnation of granular ammonium nitrate with diesel fuel, dusting with powder of coal, ammonium sulfate, etc. at the same time, when using smooth granular nitrate in its composition, technological operations of impregnation and dusting serving to increase the physical stability of the composition are not possible. Sulfur contained in ammonium sulfate during the explosion forms oxides capable of irritating the mucous membranes of the eyes and respiratory tract. In addition, the known composition has no prospects for use in the manufacture of mixing and charging machines.

An object of the invention is to ensure the completeness of energy release during the explosive transformation of a simple explosive, increasing the physical stability and detonation ability of a simple explosive.

This goal is achieved due to the quantitative ratio between the liquid and solid phases of the fuel on the basis of the parity contribution to the overall oxygen balance of the fuel while ensuring a zero oxygen balance of the simplest explosive, and the stability of the simplest explosives - by the properties of the components used: granular ammonium nitrate (specific surface, shape and size of granules , the presence and size of pores and cavities in granules, surface roughness), liquid fuel (viscosity characteristics of petroleum products), solid fuel (fi the physicochemical and adhesive properties of the powders, the dispersion of the composition, the shape and size of the particles). In addition, the chemical composition, physicotechnical, thermal properties, structure and structure of AS granules affect the detonation ability of mixed systems.

The amount of retained liquid fuel increases with an increase in the specific surface area of AC pellets. The structure and structure of the granules are essential characteristics that determine the possibility of manufacturing physically stable mixed simplest explosives.

In addition, the pre-ground ammonium nitrate used to increase the adhesion ability of the solid phase of the fuel is replaced with alkali metal nitrates.

The manufacture of a simple explosive and the method is implemented as follows.

The composition of a simple explosive includes an oxidizing agent in the form of powder materials, for example: pre-ground ammonium nitrate, as well as granular ammonium nitrate and fuel in the form of a liquid and a solid phase, while to ensure the completeness of energy release during explosive conversion of a simple explosive, the quantitative ratio between liquid and solid the phases of the fuel are determined on the basis of the parity contribution to the overall oxygen balance of the fuel while ensuring a zero oxygen balance of the simplest explosive, while the physical the explosiveness of explosives is enhanced due to the increased adhesion ability of the solid phase of the fuel provided when using powders of a fractional composition of -0.5 + 0.063 mm with an anisodiametric coefficient of particle shape of 1-6, as well as powdery materials with chemical affinity with an oxidizing agent, with a ratio of 0.015-0.030 by weight of the granular HAS in the explosive composition.

The amount of fuel, consisting of a liquid and solid phase, is calculated to ensure zero oxygen balance of the simplest explosive, and the adhesion of granular ammonium nitrate to fuel is enhanced by solid fuel powders having a fractional composition of -0.5 + 0.063 mm, the particle shape anisodimetricity coefficient 1-6 and pre-ground ammonium nitrate, the amount of which is 0.015-0.030 by weight of granular ammonium nitrate (GAS).

For the manufacture of the simplest explosive, granular ammonium nitrate - 1 is poured into the mixer, then solid fuel, which is either coal powder, or coke breeze, or rubber crumb, is fed and mixed, then pre-crushed ammonium nitrate is fed and liquid fuel is poured into the resulting mixture ( diesel fuel, solar oil, etc.).

The stability of the simplest explosives is influenced by the physicochemical properties of the components used: ammonium nitrate (specific surface, shape and size of granules, the presence and size of pores and cavities in granules, surface roughness), liquid petroleum products (viscosity characteristics of petroleum products), and solid fuel (physical chemical and adhesive properties of powders, dispersion of the composition, shape and size of particles). The detonation ability of mixed systems is influenced by the chemical composition, physicotechnical, thermal properties, structure and structure of HAS granules.

The amount of retained diesel fuel increases with an increase in the specific surface area of HAS granules. The structure and structure of the granules are essential characteristics that determine the possibility of manufacturing physically stable mixed simplest explosives. The study of the solid phase of the fuel - the dispersed composition of the rubber crumb of TU 2511-001-33068450-2014, coke breeze (JSC Razrez Berezovsky), coal (Tugnuiskiy cut), carried out using FRITSCH SPARTAN vibrating screens, showed the following distribution parameters for fractions (see table).

Studies of the shape of solid fuel particles showed that particles of rubber crumb of a fraction of -0.063 mm have the shape of a rectangle with sizes from 30-40 × 70-100 μm, square with sizes from 60 × 60 to 80 × 80 μm, trapezoid with sizes from 50 × 60 up to 70 × 80 microns. There are individual particles of a rounded shape with a diameter of 50-70 microns. Particles of irregular shape ranging in size from 30 × 50 to 60 × 100 microns. The coefficient of anisodiametric shape (dmax / dmin) of particles of rubber crumb fraction -0, 063 mm is 1-2.5.

Particles of coke fines, for example, fractions of -0.063 mm approach the shape of a rectangle with sizes from 7.8 × 15.68 to 29.68 × 60.42 μm, trapezoid with sizes from 10.53 × 14.28 to 31.47 × 49.14 μm, rhombus with sizes from 13.08 × 16.76 to 33.88 × 49.31 μm. The coefficient of anisodiametric shape of the particles of coke breeze fraction -0.063 mm is 1.4-3.5.

The particles of coal dust fraction -0,063 are characterized by the following geometric parameters of the particles: square with sizes from 4.7 × 4.7 to 10.0 × 10.0 mm; a rectangle with dimensions from 3.1 × 6.3 to 8.4 × 29.4 mm; trapezoid with sizes from 2.0 × 3.67 to 10.4 × 20.9 mm; isosceles triangle with dimensions from 1.8 × 3.3 to 13.5 × 19.7 mm. The anisodiametricity coefficient of the form of particles of coal dust crumbs fractions of -0.063 mm is from 1-6.

The distribution of solid fuel powders is influenced by the surface properties of HAC granules (including the macroporosity of the granules), the shape and surface roughness of the powder material. The distribution of solid fuel particles (coke breeze and coal powder) over the surface of AS granules shows that when the powder concentration changes from 1.5 to 2.5%, coke breeze is retained on the surface of GAS granules 0.5-0.66%, 0.62 -0.98% of coal powder, which indicates their different adhesive ability.

Studies of powder materials (coke breeze and coal powder) have revealed the influence of the shape of the material on the adhesion ability of HAS granules. Particles with an anisodiametricity coefficient of 1-6 have the best adhesion.

To determine the quantitative relations between the liquid and solid phases of fuel in the simplest explosive, consisting of ammonium nitrate, liquid fuel (LH) and coke or coal powder, the following assumption is used: there are 100 (g) NH ₄ NO ₃ , x (g) LH and y (d) coke or coal. Oxygen balance - KB (NH ₄ NO ₃ ) = 0.2; KB (LH) = - 3.47; KB (coke or coal) = - 2.667. When the ratio of the oxygen balance of coke or coal to liquid fuel is equal to 2.667 / 3.47, the parity ratio (parity contribution, parity assumption, etc.) is 40% / 60%. The ratios between the oxidizing agent and the fuel are determined and the equation is made:

100⋅0.2 + (- 3.47) ⋅0.4x + (- 2.667) ⋅0.6y = 0

y = 1.5x

Conduct a conversion

100⋅0.2 + (- 3.47) ⋅0.4x + (- 2.667) ⋅0.6 1.5x = 0.

The solution to the system is

x = 5.27 g

y = 7.9 g

and get a mass ratio of components:

m (NH ₄ NO ₃ ) = 100 (g)

m (DT) = 5.27 (g)

m (coke or coal) = 7.9 (g)

The mass balance is 100 + 5.27 + 7.9 = 113.17 g. As a percentage, the ratio of the components of the simplest explosive will be: the content of the AC is 88.36%; liquid fuel - 4.66%, coke or coal - 6.98%. The technological ratio between the liquid and solid phases of the fuel, taking into account rounding, is 4.5% and 7%, respectively.

For the manufacture of the simplest explosive, granulated ammonium nitrate GAS is poured into the mixer, then solid fuel, represented by rubber crumb, is fed and mixed, then pre-ground ammonium nitrate is fed and liquid fuel is poured into the resulting mixture.

To determine the quantitative relations between the liquid and solid phases of the fuel in the simplest explosive, consisting of ammonium nitrate, liquid fuel (LF) and crumb rubber (RK), the following assumption is used. To make the simplest explosive, granular ammonium nitrate is poured into the mixer, then solid fuel (TG), represented by rubber crumb, is fed and mixed, then pre-ground ammonium nitrate is fed into the mixture, liquid fuel (LG) is poured into the mixture and a three-component explosive mixture consisting of from granular ammonium nitrate, liquid fuel (LF) and solid fuel (crumb rubber) with zero oxygen balance. For example: they have 100 (g) NH ₄ NO ₃ , x (g) GH and y (g) rubber crumb. CB (NH ₄ NO ₃ ) = 0.2; KB (LH) = - 3.47; KB (rubber crumb) = - 3.259.

With the ratio of fuel KB (DT and rubber crumb) equal to 3.47 / 3.259, the parity ratio of LH and powder of butadiene rubber monomer is about 50% / 50%. Carry out the determination of the relationship between the oxidizing agent and the fuel, for this we make the equation:

100⋅0.2 + (- 3.47) ⋅0.5x + (- 3.259) ⋅0.5y = 0

x = y

The solution to the system is

then we get the mass ratio of components:

m (NH ₄ NO ₃ ) = 100 (g)

m (DT) = 2.438 (g)

m (crumb rubber) = 2,438 (g)

The mass balance is 100 + 2.348 + 2.348 = 104.696 g. As a percentage, the ratio of the components of the simplest explosive will be: AC content - 95.5%; ZhG - 2.25%, crumb rubber - 2.25%. The technological ratio between the liquid (LF) and solid (rubber crumb) phases of the fuel, taking into account rounding, is 2.25% and 2.25%, respectively.

Options:

To make the simplest explosive, granular ammonium nitrate is poured into the mixer, then liquid fuel is separately mixed with solid fuel, represented either by coal powder, or coke breeze, or crumb rubber, then mixed with granular nitrate, and then pre-ground ammonium nitrate is fed.

To make the simplest explosive, granular ammonium nitrate is poured into the mixer, and then pre-crushed ammonium nitrate is fed, then the liquid fuel is separately mixed with solid fuel represented by either coal powder, or coke breeze, or crumb rubber and the resulting mixture is fed into the mixer.

For the manufacture of the simplest explosive, pre-ground ammonium nitrate is fed into the mixer, then granular ammonium nitrate is poured, the liquid fuel is separately mixed with solid fuel, either coal powder, coke breeze, or crumb rubber and fed to the mixer.

For the manufacture of the simplest explosive, pre-ground ammonium nitrate is fed into the mixer, liquid fuel is mixed separately with solid fuel represented by either coal powder, coke breeze, or crumb rubber, and granular ammonium nitrate is then added to the mixer.

To make the simplest explosive, liquid fuel is separately mixed with solid fuel, represented either by coal powder, or coke breeze, or crumb rubber, and the resulting mixture is fed into the mixer, then pre-ground ammonium nitrate is fed into the mixer, then granular ammonium nitrate is poured.

In addition, the use of pre-ground ammonium nitrate is replaced with alkali metal nitrates i.e. to increase the adhesion ability of the solid phase of the fuel, i.e. replaced with other types of nitrate: potassium, sodium.

Claims (9)

1. The composition of the simplest explosive (BB), including an oxidizing agent in the form of granular ammonium nitrate and powder material and fuel in the form of a liquid and a solid phase, characterized in that the quantitative ratio between the liquid and solid phases of the fuel is determined on the basis of the parity contribution to the overall oxygen balance fuel while ensuring zero oxygen balance of the simplest explosives, contains petroleum products as the liquid phase of the fuel, contains coal powder, coke breeze or rubber as the solid phase crumb, using powders of a solid phase of a combustible fractional composition of -0.5 + 0.063 mm with an anisodiametric coefficient of particle shape of 1-6, as powder materials it contains pre-ground ammonium nitrate or alkali metal nitrates in an amount of 0.015-0.030 by weight of the granular ammonium nitrate as part of explosives. 2. A method of manufacturing a simple explosive, comprising mixing an oxidizing agent in the form of granular ammonium nitrate and a powdery material with fuel in the form of a liquid and a solid phase, characterized in that the quantitative ratio between the liquid and solid phases of the fuel is determined on the basis of the parity contribution to the overall oxygen balance of the fuel while ensuring zero oxygen balance of the simplest explosive, oil products are used as the liquid phase of the fuel, coal powder is used as the solid phase, ox fines or rubber crumbs, using powders of a solid phase of a combustible fractional composition of -0.5 + 0.063 mm with an anisodiametric coefficient of particle shape of 1-6, as powder materials contains pre-ground ammonium nitrate or alkali metal nitrates in an amount of 0.015-0.030 by weight of granular ammonium nitrate in the composition of the explosive. 3. The method according to p. 2, characterized in that granular ammonium nitrate is poured into the mixer, then solid fuel is fed and mixed, then powder material is fed and liquid fuel is poured into the resulting mixture. 4. The method according to p. 2, characterized in that granular ammonium nitrate is poured into the mixer, then solid fuel, which is rubber crumb, is fed and mixed, then powder material is fed and liquid fuel is poured into the resulting mixture. 5. The method according to p. 2, characterized in that granular ammonium nitrate is poured into the mixer, liquid fuel and solid fuel are mixed separately, the resulting mixture is mixed with granular ammonium nitrate, and then powder material is fed. 6. The method according to p. 2, characterized in that granular ammonium nitrate is poured into the mixer, and then powder material is fed, liquid fuel and solid fuel are mixed separately, and the resulting mixture is fed into the mixer. 7. The method according to p. 2, characterized in that the powder material is fed into the mixer, then granular ammonium nitrate is poured, liquid fuel and solid fuel are mixed separately, and the resulting mixture is fed into the mixer. 8. The method according to p. 2, characterized in that the powder material is fed into the mixer, liquid fuel and solid fuel are separately mixed and fed into the mixer, then granular ammonium nitrate is poured. 9. The method according to p. 2, characterized in that the liquid fuel is separately mixed with solid fuel and the resulting mixture is fed into the mixer, then powder material is fed into the mixer, after which granular ammonium nitrate is poured.