RU2384554C2 - Explosive mixture - Google Patents

Abstract

FIELD: explosives.

SUBSTANCE: explosive mixture includes 0.5 - 1.5 wt % of potassium nitrate, 7.0 - 9.0 wt % of dinitronaphthalene, 7.0 - 9.0 wt % of trotyl and ammonium nitrate (the rest).

EFFECT: improving the safe use of explosive mixture owing to reduction of susceptibility to mechanical effects and toxicity of composition, increasing the efficiency owing to high apparent density.

3 tbl, 2 cl

Description

The invention relates to waterproof industrial explosives (BB), namely ammonium nitrate, intended for open and underground work, with the exception of mines and mines hazardous by gas or dust.

Among the known explosive mixtures, ammonium nitrate explosives are of the greatest practical importance. A variety of conditions for the use of explosives in the mining industry, construction, and for many other industrial purposes, as well as in military equipment, impose stringent requirements on blasting explosives of this class.

Explosives should have high power, while being safe to handle, have sufficient sensitivity to the initial impulse, be stable during storage and certain conditions of their use.

Known industrial explosive Ammonite No. 6ZHV (GOST 21984-76), which is widely used at the present time for loading holes and wells during blasting in the mining industry.

The specified industrial explosive Ammonite No. 6ZHV consists of 79% of the oxidizing agent - ammonium nitrate and 21% of explosive fuel - trotyl or granulotol grade A.

Despite the large values of energy and detonation characteristics and a fairly high level of brisance (14-15 mm), Ammonite No. 6ZHV has a number of significant drawbacks. This is primarily due to the low level of safety in its manufacture and use due to the presence in the explosive mixture of a significant amount of TNT, which has a harmful effect on humans and the environment (MPC = 0.5 mg / m ³ ), as well as having high sensitivity to mechanical stress. In addition, the production of TNT is an environmentally hazardous production. Based on these considerations, in developed countries both production and the use of TNT in peacetime are sharply limited.

The use of high content of expensive TNT leads to an increase in the cost of explosives.

The introduction of potassium nitrate into ammonites is also known. The amount of potassium nitrate introduced is usually at least 10% (B.Ya. Svetlov et al. Theory and properties of industrial explosives, Moscow, 1973, ed. Nedra, p.106). However, the introduction of such an amount of potassium nitrate reduces brisance and creates conditions under which the explosive does not function from standard means of initiation.

By its technical nature and the achieved result, the mixture closest to the developed explosive mixture is ammonium nitrate and a blasting explosive consisting of dinitronaphthalene and TNT (RU No. 2253643 C1, June 4, 2002, description - Table 5, sample No. 39). The components of this sample are contained in the following amounts, wt.%: A mixture of dinitronaphthalene with TNT - 38.3, ammonium nitrate - 61.2. In the known mixture also contains liquid fuel - 0.5 wt.%, Which can be used liquid petroleum products, vegetable or coal oils in order to use this explosive mixture in waterlogged wells.

When using powdered metallic and organic fuels, the technology of the final product becomes more laborious.

The explosive of the prototype contains a significant amount of TNT (more than 22 wt.% Mixed with dinitronaphthalene as a combustible component, which is comparable with the amount of TNT contained in Ammonite No. 6ZHV). This increases the level of its toxicity and reduces the safety of use, and the presence of liquid fuel as one of the components complicates the technology of obtaining the final product and increases energy consumption.

The content of the oxidizing agent only in the form of ammonium nitrate does not allow regulating the oxygen balance. In this case, the introduction of ammonium nitrate in two aggregate states: in the form of an aqueous solution and in the form of a solid substance significantly complicates the technology, negatively affects the explosive characteristics, reduces the explosion energy, and the presence of even a small amount of moisture leads to failures and incomplete detonation of cartridges.

The objective of the present invention is to improve the basic explosive properties (brisance, critical detonation diameter, detonation speed), increase the safety of explosives, reduce the toxicity of the composition, reduce the consumption of TNT and lower the cost of industrial explosives.

The problem is solved in that the explosive mixture, including ammonium nitrate and blasting explosive, consisting of dinitronaphthalene and TNT, additionally contains potassium nitrate in the following ratio of components, wt.%:

Potassium nitrate 0.5-1.5 Dinitronaphthalene 7.0-9.0 TNT 7.0-9.0 Ammonium nitrate rest

As TNT, this mixture may contain brand A granulotol.

In the proposed composition of explosives, liquid fuel is completely excluded, and the nitrate part, in contrast to the known composition, is represented by two ingredients - potassium and ammonium nitrate.

In the composition of the explosive, waterproof granular or crystalline ammonium nitrate (GOST 14702-79) is used as an oxidizing agent, which also plays the role of an antistatic additive that prevents the accumulation of charges of static electricity, which increases the safety of the manufacture and use of explosive mixtures.

The introduction of potassium nitrate - potassium nitrate (GOST 19790-74) in an amount of 0.5-1.5 wt.%, That is, in an amount significantly less than the prototype increases the brisance, creates the conditions for the operation of explosives from standard means of initiation, and also allows use potassium nitrate as an additional oxidizing agent in adjusting the oxygen balance to reduce the amount of explosion products.

As an explosive fuel, trotyl (GOST 411778) or granulotol grade A (GOST 25857-83), which is both a combustible, sensitizer, and energy-carrying component of the inventive explosive mixture, are used.

As an additional explosive fuel, dinitronaphthalene (GOST 6599-76) is used, the introduction of which into the explosives by reducing the amount of TNT allows to increase the safety of transportation, storage of explosives and blasting due to the higher MPC and low sensitivity to mechanical stress, i.e. . the component simultaneously performs the functions of a phlegmatizer.

Compared with the prototype, the mixture is a low-explosive explosive and it is produced using a special technology by mixing ammonium nitrate, technical dinitronaphthalene, TNT and potassium nitrate.

In this case, the starting components must meet certain requirements with respect to their moisture content and particle size distribution. After mixing, the finished ammonite powder is patronized. The technology of the explosive composition is simple, does not require sophisticated equipment and is easily feasible in existing industries of the corresponding profile and does not require significant costs. Whereas the prototype requires the organization and creation of new technological processes and the conduct of additional examinations of industrial safety both in production and in application.

The technical essence of the invention is illustrated by the following experimental data.

Table 1 shows the formulations of explosive compositions by examples of specific performance, and in table 2 their explosive-technical and energy characteristics in comparison with the prototype, in table 3 are the results of control tests of explosives with potassium nitrate content in the declared boundary values and with potassium nitrate content beyond these values.

It is known that the mechanical effect of an explosion for blasting explosives is estimated by the crushing action, which is manifested in close proximity to the charge. The crushing effect of the blasting explosives is associated with the speed of detonation and bulk density, and the introduction of explosive potassium nitrate significantly increases its bulk density to 1120 kg / m ³ compared to the prototype (see table 2 of the description of the invention).

The test results presented in table 2 show that, unlike the prototype, the pieces of the claimed composition are less sensitive to mechanical stress, and the composition according to the invention is not inferior to the prototype in terms of basic energy and detonation properties.

A comparative analysis of the technical characteristics of explosives of various compositions based on ammonite, shown in table 3, shows that the introduction of potassium nitrate only in predetermined proportions provides a new positive effect. An increase or decrease in the amount of potassium nitrate in the explosive composition negatively affects the main characteristics of the explosive, namely it reduces brisance and creates the conditions under which the explosive does not function from standard means of initiation.

The claimed multicomponent composition of the explosive allows you to get the optimal oxygen balance, which provides the necessary parameters for the functioning of cartridges with a diameter of 32 mm, including providing a standard indicator for brisance and the possibility of failure-free initiation. These indicators for cartridges of this type are decisive.

The closest analogue of the cartridge in question is a cartridge with a diameter of 32 mm from ammonite 6ZHV. The disadvantage of this analogue is the presence of TNT (21%), which is its main disadvantage due to the high danger and environmental impact on the environment.

The technical effect in this invention is achieved due to the selected components, their quantitative ratio, providing optimal values of the completeness of the chemical transformation, oxygen balance, stability of the component composition. That is, the invention provides a different, previously unknown component composition.

Low-explosive explosive mixture corresponding to this invention was tested to obtain positive results when breaking rocks of various strengths (with a coefficient of strength up to 20 on the M. M. Protodyakonov scale).

Wells were charged manually using the existing blasting technology using standard charge initiation systems. The explosive mixture does not dust, does not cake, and is stable during storage and use.

The real explosive under the technical name Ammonite No. 6ZHV-DNN is sold for industrial use. The term "ammonite" is adopted in accordance with the requirements of regulatory documentation for reference to a specific group of explosive materials for industrial use.

Table 1 Explosive components Content in composition,% (mass fraction) Prototype Execution examples one 2 3 Potassium nitrate - 1,5 1,0 0.5 Dinitronaphthalene * 9.0 8.0 7.0 TNT or granulotol brand A 38.3 7.0 8.0 9.0 Ammonium nitrate 61.2 82.5 83.0 83.5 Note: * - in the prototype dinitronaphthalene (DNN) is indicated in a mixture with TNT (DNN + TNT)

table 2 Basic explosive, technical and energy characteristics prototype The compositions of table 1, for examples one 2 3 Brisance, mm (GOST 5984-80) 13 14.5 14.7 14.7 Sensitivity to mechanical stress: - sensitivity to shock in the device No. 2, the lower limit, mm; (GOST 4545-88) 500 510 510 510 - sensitivity to friction on the device K-44-Sh, lower pressure limit, kgf / cm ² (GOST R 50835-95) 3365 3420 3433 3435 Bulk density, kg / m ³ 820 1120 1120 1120 Knock speed, km / s 4.2 3.6 3.8 3.9 The critical diameter of the detonation of an open charge, mm twenty 12 12 12 Susceptibility to detonation impulse Do not standardize Flawlessly detonates from industrial explosives approved for continuous use

Table 3 The results of control tests of ammonite 6ZHV-DNN TU 7276-002-54900763-2007 with different contents of potassium nitrate Name of components The content of components,% Oxygen balance,% Brisance, mm one Ammonium nitrate 82.5 Potassium nitrate 1,5 +0.05 14.8 TNT + DNN 16,0 2 Ammonium nitrate 83.25 Potassium nitrate 0.75 -0.09 15,2 TNT + DNN 16,0 3 Ammonium nitrate 83.5 Potassium nitrate 0.5 -0.06 14.2 TNT + DNN 16,0 four Ammonium nitrate 83.6 Potassium nitrate 0.4 -0.26 11.0 TNT + DNN 16 5 Ammonium nitrate 83.8 Potassium nitrate 0.2 +0.2 13.0 TNT + DNN 16,0 6 Ammonium nitrate 82.0 Potassium nitrate 2.0 +0.15 13.0 TNT + DNN 16,0 7 Ammonium nitrate 80.0 Potassium nitrate 4.0 +0.5 12.9 TNT + DNN 16,0 8 Ammonium nitrate
Potassium nitrate 77.0
7.0 +1.1 12,2 TNT + DNN 16,0 9 Ammonium nitrate 74.0 Potassium nitrate 10.0 +1.72 11.9 TNT + DNN 16,0

Claims (2)

1. An explosive mixture comprising ammonium nitrate and a blasting explosive consisting of dinitronaphthalene and TNT, characterized in that it additionally contains potassium nitrate in the following ratio of components, wt.%:
Potassium nitrate 0.5-1.5 Dinitronaphthalene 7.0-9.0 TNT 7.0-9.0 Ammonium nitrate Rest 2. The explosive mixture according to claim 1, characterized in that as TNT it contains granulotol brand A.