RU2086524C1 - Explosive composition and a method of its making - Google Patents

Abstract

FIELD: explosive materials. SUBSTANCE: composition has, %: dibasic fuel, 20-99.8; sensibilizing agent, 0.02-75.0; and retarder, the balance. Sensibilizing agent: monobasic fuel or hexagen, or octogen, or aluminium, or aluminium-magnesium alloy, or oxides, or metal salts, or multicomponent mixture. Retarder: industrial or equipment oil, or their mixture with ammonium nitrate, or multicomponent mixture. Method of making the composition involves grinding dibasic fuel under water, drying the prepared particles with air at 60-90 C, retardation and sensibilization. EFFECT: enhanced quality of composition. 5 cl, 2 tbl

Description

 The invention relates to explosive compositions obtained by the processing of dibasic fuels, and to a method for their manufacture for use as industrial explosives (PVV).

 Known explosive composition [1] consisting of explosive components - nitrocellulose, nitroglycerin and blasting explosives in finely divided form (for example, hexogen, pentaerythritol tetranitrate, nitroguanidine, etc.), and the amount of blasting explosive is from 20.85 to 34.4% of the mixture explosive components.

 Known explosive composition "Granipor" used as PVV, based on dibasic fuel and phlegmatizer [2] adopted as a prototype for the inventive explosive composition.

 The complexity of the problem of the processing of dibasic fuels into PVV consists in lower susceptibility to detonation impulse and increased sensitivity to mechanical stress compared to regular PVV (for example, trotyl-containing).

 The aim of the invention is to increase the efficiency of explosive compositions by expanding the scope of their application, increasing the uptime, reducing the risk of manufacture and use.

The goal is achieved by creating an explosive composition (BC) containing a dibasic fuel, a phlegmatizer and, in addition, as a sensitizer, a monobasic fuel or hexogen, or octogen, or an aluminum-magnesium alloy, or metal oxides and salts, or a multicomponent composition, including (wt.):
Colloxylin 5.8
Pyroxylin 14.17
Nitroglycerin 18.25
Centralit 0.7.1.5
Instrument or industrial oil 0.8.1.2
Technical carbon 0,15.0,25
Barium sulfate 2.0.4.0
Titanium dioxide 4.0.6.0
RDX Rest,
while the components included in the following ratio, wt.

Dibasic fuel 20.99.8
Sensitizer 0.02.75.0
Phlegmatizer Else
It is the introduction of a sensitizer in the sun that increases the susceptibility of dibasic fuel to the detonation pulse, increases the effectiveness of the sun. The proposed aircraft allows you to process all grades of dibasic fuels and all standard sizes of charges with the manufacture of PVV widely used: for the destruction of oversized, open mining during exploration and mining.

Reducing sensitivity to mechanical stresses, ensuring the safety of transportation, storage and blasting is achieved by phlegmatization of the aircraft by introducing industrial or instrument oil or a mixture of oil and ammonium nitrate in a ratio of 3: 500 to 3:40, or cellulose, as a phlegmatizer material, or multicomponent composition, including (wt.):
Iron or copper or nickel powders 80.90
Colloxylin 4.0.8.0
Dibutyl phthalate 4,5.8,6
Triacetin 1.0.2.5
Teflon 0.3.0.6
Diphenylamine 0.08.0.1
Industrial or instrument oil 0.08.0.14
Zinc stearate or graphite, or magnesium or nickel oleates, or a mixture thereof in a ratio of 1: 1: 1 0.04.0.06
Depending on the area of application of the charges of the proposed aircraft, based on the requirements for ensuring safety and trouble-free operation of the charge, the ratio between the dibasic fuel, phlegmatizer and sensitizer varies, the type of dibasic fuel used and the amount of phlegmatizer and sensitizer are selected.

 Examples of the proposed explosive composition, the main properties and applications of the aircraft charges are given in table. one.

 Known methods for the manufacture of PVV based on dibasic fuels by treating them (locks, swelling) with an emulsion or aqueous solutions of furfural, acetone, followed by grinding on runners, rollers and mixing with components of phlegmatizers, such as solutions of calcium nitrate, substituted urethanes, and other disadvantages of these methods are the duration of the technological cycle, the inability to process large-sized products, high complexity and cost.

 A known method of manufacturing explosives by grinding powder [3] adopted as a prototype of the proposed method for the manufacture of explosive composition based on dibasic fuel.

The method consists in grinding the charges of dibasic fuel under water, the resulting particles (elements) are dried with air at a temperature of 60-90 ^o C, phlegmatized by spraying instrument or industrial oil or its mixture with ammonium nitrate, or coextrusion with a multicomponent phlegmatizer, and then sensitize.

Obtained by grinding charges of dibasic fuel fuel cells have a bulk density of 0.65.0.75 g / cm ³ . If it is necessary to obtain particles with a higher bulk density (0.8.1.1 g / cm ³ ), the crushed and dried fuel particles are granulated before phlegmatization. Granulation is carried out, for example, in an extruder at a temperature of 70-90 ^o C. The extruder is equipped with a screw screw with a drive heated by a die and a rotary knife, the torque to which is transmitted through the gearbox from the extruder drive, while the rotational speed of the knife is proportional to the rotational speed of the screw screw, which provides granules of constant length in the entire range of frequencies of rotation of the extruder.

Example 1. The dibasic fuel in the form of fine-cylindrical cylindrical products is heated at a temperature of 60.90 ^o C and cut under water into particles of 2.20 mm, which are then blown with air at a temperature of 40.90 ^o C to remove surface moisture. The resulting particles are phlegmatized with oil by spraying it or mixed with a mixture of oil and ammonium nitrate. A monobasic fuel sensitizer is introduced into the resulting composition by mechanical stirring. This method is used to produce explosive compositions (wt.), Are given in table. 2.

 Explosive compositions I are among the waterproof industrial explosives. Indicated in the table. 2 compositions are made and tested as borehole charges under industrial conditions of the Teplogorsk crushed stone plant. Waterlogged wells, water column height up to 5 m.

The rock strength coefficient according to the Protodyakonov scale is 20. The diameter of the wells is 269 mm, the depth is 16.20 m, the drilling network is 5.5x5.5 m. The blasting pattern is decent with a delay between rows of 20 ms. The quality of crushing the rock is satisfactory, the shape of the collapse is compact, there are no reverse emissions and oversize. The specific consumption of 1.06 kg / m ³ .

Explosive compositions II are among the industrial explosives of limited water resistance and are recommended for charging dry wells with running water. These compositions are manufactured and tested in industrial conditions of the Krasnoyarsk SU Association "Soyuzvzryvprom". Wells are dry. The coefficient of fortress according to the Protodyakonov scale 5. The diameter of the wells is 220 mm, the depth is 17.7.19.5 m, the drilling grid is 6.5x6.5 m. The blasting pattern is diagonal with a trapezoidal cut. The quality of rock crushing is satisfactory, the collapse is normal, the cast for the last row of wells is negligible. Oversize is missing. The specific consumption of 0.5 kg / cm ³ .

Example 2. Dibasic fuel with a burning arch thickness of 10.40 mm is heated in water at a temperature of 80.90 ^o C, cut into elements along the length, which are phlegmatized with industrial or instrument oil, or with a mixture of oil and ammonium nitrate and mixed with a sensitizer.

To increase the bulk density of the explosive composition to 1.1 g / cm ³ additional granulation of the particles is carried out by extrusion at a temperature of 70.90 ^o C on elements with a length of 2.8 mm, phlegmatize and mix them with a sensitizer.

 This method is used to produce explosive compositions (wt.), Are given in table. 3.

 Explosive compositions III, IV, V are manufactured in the factory and tested as borehole charges in an industrial environment (see table. 4).

Example 3. An explosive composition containing (wt.):
Dibasic fuel 73.8
Multi-component sensitizer 25.8
Multicomponent phlegmatizer 0.4
manufactured analogously to example 2. Phlegmatization is carried out with a multicomponent phlegmatizer, including (wt.): 80.90 powders of iron, or copper, or nickel; 4.0.8.0 colloxylin; 4,5.8,6 dibutyl phthalate; 1.0.2.5 triacetin; 0.3.0.6 fluoroplastic; 0.08.0.1 diphenylamine; 0.08.0.14 vaseline or instrument oil; 0,04,0,06 technological additives (stearic acid zinc or graphite, or magnesium oleate, or a mixture in a ratio of 1: 1: 1), by extrusion at a temperature of the press and extrusion head 85.90 ^o C.

Test Results:
Knock speed, km / s 7300
The critical diameter of the detonation, mm 3.5
The completeness of detonation from 3 threads DSA, 100
Example 4. An explosive composition containing (wt.):
Dibasic fuel 99.7
Multi-component sensitizer 0.2
Phlegmatizer 0.1
made as described above, fuel cells after drying are phlegmatized by gluing with cellulosic material in the form of paper.

 A multi-component sensitizer consists of the following components, wt.

Colloxylin 7.0
Pyroxylin 15.4
Nitroglycerin 22.4
Centralit 1.0
Industrial oil 1.0
Technical carbon 0.2
Barium sulfate 3.0
Titanium dioxide 5.0
RDX 45.0
Explosive Test Results:
Critical diameter mm 3.0
Knock speed, km / s 7.0
Sensitivity to shock, frequency of explosions, 40
Detonation completeness in flooded wells, 100t

Claims (2)

 1. An explosive composition comprising a dibasic fuel and a phlegmatizer, characterized in that it additionally contains as a sensitizer a monobasic fuel, or RDX, or HMX, or aluminum, or an aluminum-magnesium alloy, or metal oxides and salts, or a multicomponent composition, including wt. Colloxylin 5 8
Pyroxylin 14 17
Nitroglycerin 18 -25
Centralit 0.7 1.5
Instrument or industrial oil 0.8 1.2
Technical carbon 0.15 0.25
Barium sulfate 2.0 4.0
Titanium dioxide 4.0 6.0
RDX Rest
and the incoming components are taken in the following ratio, wt. Dibasic fuel 20 99.8
Sensitizer 0.02 75.0
Phlegmatizer Else
2. The composition according to claim 1, characterized in that as a phlegmatizer contains industrial or instrument oil, or a mixture of instrument or industrial oil and ammonium nitrate in a ratio of from 3,500 to 3,40, or cellulosic material, or a multicomponent composition comprising, by weight . Powders of iron or copper or nickel 80 -90
Colloxylin 4.0 8.0
Dibutyl phthalate 4.5 8.6
Triacetin 1.0 2.5
Ftoroplast 0.3 0.6
Diphenylamine 0.08 0.1
Industrial or instrument oil 0.08 0.14
Zinc stearate, or graphite, or oleates of magnesium or nickel, or a mixture thereof in a ratio of 1 1 1 0.04 0.06
3. A method of manufacturing an explosive composition, including grinding charges of dibasic fuel, characterized in that the grinding of fuel is carried out under water, the resulting particles are dried with air at 60 90 ^o C, phlegmatized by spraying instrument or industrial oil or its mixture with ammonium nitrate or coextrusion with multicomponent phlegmatizer, and then sensitize.  4. The method according to claim 3, characterized in that the crushed and dried particles of dibasic fuel are granulated before phlegmatization.

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