RU2033521C1 - Method for blasting overburden hard rocks and minerals, versions - Google Patents

Abstract

FIELD: equipment for drilling and blasting. SUBSTANCE: method for blasting overburden hard rocks and minerals includes operations for hole drilling, hole charging with explosives having preliminarily introduced coal powder. Additionally introduced into explosive are liquid oil products in volume of 1-4%, and coal powder of 2-20% with fractions sizing from 3·10^-5 to 1·10^-3 m and content of vitrinite of 75 to 99 mas.%. In the other version, introduced additionally into explosive mixture is coal powder in volume of 30% with fractions sizing from 1·10^-3 to 3·10^-3 m. Besides, explosive may be used in form of ammonium nitrate. EFFECT: higher efficiency. 4 cl, 7 tbl

Description

 The invention relates to drilling and blasting operations and can be used for mining during the explosive preparation of rock overburden and mineral, in particular a corner, in deposits developed by open pit mining.

 A known method of explosive cleaning of rock overburden and minerals, including drilling holes or wells, loading them with explosives (BB) and blasting (Kutuzov BN Blasting operations. M. Nedra, 1980, p. 4).

 The disadvantage of this method is the significant loss of minerals in its application due to regrinding, scattering and mixing with overburden, as well as poor crushing of the enclosing rocks and high consumption of explosives. In addition, the explosion of industrial explosives produces a significant amount of toxic gases, which negatively affects environmental factors.

 The problem to which the invention is directed, is to increase the efficiency of blasting and improve environmental conditions in the extraction of minerals.

 The technical result of the invention is to improve the detonation ability of explosive mixtures, reducing their consumption and reducing the level of emission of toxic gases.

 To solve the problem with the achievement of the specified technical result, at least two main variants of the invention are possible.

For the first option, in the known method of explosive breaking of rock overburden and minerals, including drilling wells, charging them with explosive, coal powder is preliminarily introduced into the explosive and liquid petroleum products are additionally introduced in a volume of 1-4% and coal powder is introduced in a volume of 2- 20% with fractions ranging in size from 3˙10 ^-5 to 1˙10 ^-3 m and a vitrinite content of 75 to 99 wt.

For the second option, in the known method of explosive breaking of rock overburden and minerals, including drilling wells, charging them with explosive, coal powder is preliminarily introduced into the explosive and liquid petroleum products are additionally introduced in a volume of 1-4% and coal powder is introduced in a volume of 2- 20% with fractions ranging in size from 3˙10 ^-5 to 1˙10 ^-3 m and a vitrinite content of 75 to 99 wt. and in volume up to 30% with fractions from 1˙10 ^-3 to ³ -10 ^-3 m in size.

 In addition to the first and second main options, an embodiment of the invention is possible in which it is advisable to use ammonium nitrate as the explosive.

 When conducting blasting operations by known methods, depending on the degree of resistance of the rock mass, various types of explosives are used (grammonites, granulites, igdanites, water-filled explosives, etc.). In this case, a significant consumption of explosives is required, which leads to a significant level of emission of toxic gases (carbon oxides and nitrogen) during explosion. In addition, igdanites, for example, have a low detonation ability due to the separation of explosive components (runoff of liquid oil), which creates the prerequisites for unreliable detonation and incomplete energy release during an explosion.

 The introduction of a filler in explosives or ammonium nitrate in the form of coal of various fractional and petrographic composition, especially in large quantities (more than 50%) leads to a deterioration in the detonation ability of explosive mixtures up to the burning of charges when using simple explosives. In addition, due to the different densities of coal and components of explosives, the mixing of the constituents of the explosive mixture is not always ensured, which reduces the efficiency of blasting.

The introduction, in accordance with two main variants of the invention, in the composition of the explosive along with the coal powder of additional liquid petroleum products in the amount of 1-4% ensures uniform mixing of the components of the explosive mixture without significantly reducing its explosive momentum. The use of coal powder with fractions ranging in size from 3˙10 ^-5 to 1˙10 ^-3 m in a volume of from 2 to 30% and a vitrinite content of 75-99 wt. for introduction into an explosive, including ammonium nitrate, it allows to increase the explosive impulse of the charge and significantly reduce the release of toxic gases during the explosion.

The introduction into the explosive according to the second main embodiment of the invention additionally up to 30% by volume of coal powder with fractions from 1˙10 ^-3 to 3˙10 ^-3 m in size improves the mixing conditions of its components, allows you to adjust the charge volume and reduce the area of unregulated crushing of the array , which is especially important when blasting soft rocks and rocks of medium strength.

 In addition, the use of coal powder as a filler in the above fractional compositions and volumes improves the detonation ability of explosive mixtures due to the completeness of detonation of charges and helps to stabilize explosives such as igdanites.

According to the methodology of VostNII (industrial explosives. Method for determining the effectiveness of explosives for borehole charges by squeezing a lead cylinder and the height of the load load, Kemerovo, 1989), the effectiveness of the explosion of mixtures of regular explosives or nitrate with coal filler of various fractional and petrographic composition was evaluated on a test bench. The charge volume in all experiments was equal to 1000 cm ³ . The criterion for the effectiveness of the explosion was the compression of the lead cylinder, which was installed under a massive anvil, above the surface of which the test charges of this volume were located in a shell of wet sand. The shell thickness and the intermediate detonator were selected in advance so that the completeness of explosive charge conversion was ensured. The results of the tests are presented in table 1.

From the table. 1 it can be seen that the effectiveness of the explosion of explosive mixtures with coal, the particle size of which does not exceed 10 ^-3 m, is higher with a vitrinite content of more than 75%, while for explosive mixtures with a coal content with particle sizes more than 10 ^-3 m the effect of the explosion remains approximately the same and independent of the petrographic composition of coal.

According to the aforementioned methodology of VostNII, the stand evaluated the effectiveness of the explosion of explosive mixtures depending on the percentage of coal in them with particle sizes from 3 от10 ^-5 to 3˙10 ^-3 m.The charge volume in all experiments was 1000 cm ³ . The results of the tests are presented in table.2.

 From table 2 it can be seen that when the explosive contains 1-2% coal, the efficiency of the explosive mixture in comparison with regular explosives (grammonite 79/21 30.1 mm, igdanite 28 mm) practically does not decrease. At the same time, when the content of coal in grammonite 79/21 is more than 50% and in igdanite and ammonium nitrate more than 10-20%, the compression of the lead column corresponds to its compression from the industrial detonator, i.e. detonation of explosive mixtures with a large amount of coal proceeds in the mode of incomplete explosive transformation due to its dispersion in the process of explosion and burnout. In this case, the introduction of 2% coal into igdanite prevents the flow of liquid combustible additives, i.e. stabilizes explosives.

 The effectiveness of the explosion of explosive mixtures obtained by mixing 1 kg of explosives with coal, depending on the fractional composition of coal, was also determined at the aforementioned VostNII stand. The test results are presented in table.3.

From the table. 3 shows that the introduction of coal with particle sizes less than 10 ^-3 m increases the explosive impulse of charge from pure grammonite, and with an increase in the size of coal particles more than 10 ^-3 m changes the explosive impulse in the direction of its decrease, while the effectiveness of the explosion of explosive mixtures with coal the filler of the fractional composition 1˙10 ^-3 3˙10 ^-3 m is more effective than mixtures containing coal with particle sizes greater than 3˙10 ^-3 m.

Sampling of explosion products for the determination of toxic gases was carried out after the explosion of regular explosives and explosive mixtures with carbon filler in an explosive chamber with a capacity of 90 m ³ in accordance with the method for determining the volume and composition of explosion products. (Pozdnyakov Z.G. Rossi B.D. Handbook of industrial explosives and explosives, M. Nedra, 1977. S. 188-190). The results of the tests are presented in table.4.

From table 4 it is seen that during the explosion of explosive mixtures with coal, 1.5-3 times less toxic gases (carbon and nitrogen oxides) are formed than when explosives are blown without coal. In this case, a sharp decrease in toxic gases occurs when explosive mixtures containing coal with particle sizes less than 1˙10 ^-3 m are blown up.

 To determine the effect of liquid petroleum products on the brisant properties of explosive mixtures with coal filler, they were tested using steel rings in accordance with the method of determining brisance by Hess breakdown (Svetlov B. Ya. Yaremenko NE Theory and properties of industrial explosives. M. Nedra , 1973, p.133-134).

 From the table. Figure 5 shows that when the content of liquid petroleum products exceeds 4% in the compositions of the explosive mixture with coal filler, the brisance of the mixture sharply decreases, while when the content of liquid fuel in these mixtures is at the level of 1-4%, regardless of the amount of coal in the charge compositions, it remains approximately the same.

The method is based on the dependence of the explosive transformation of explosives with a coal filler on the explosive properties of coal, which are determined by its petrographic composition and particle size, which determine the speed and completeness of its combustion. It is known that a high content of vitrinite in coal increases the explosiveness of its dust, and the particle size of coal less than 10-3 m ensures that it gets into the intergranular space when mixed with explosives or AS, which increases the charge density, as a result of which the explosive impulse of an explosive increases mixtures and decreases the amount of toxic gases due to the full participation of coal in detonation. At the same time, coal with a particle size of more than 1˙10 ^-3 m is mainly an inert material, because its complete combustion requires a very long time due to its small specific surface. Therefore, it partially participates in the explosive transformation of explosives and only allows you to change the explosive momentum of the mixture in the direction of its decrease by reducing the consumption of explosives and serves as an adsorbent to reduce the yield of toxic gases.

 In this regard, the use of fine coal in explosive mixtures or its combination with coarse allows you to adjust the explosive impulse of the charge both in the direction of increasing it and in the direction of decreasing it depending on the strength of the rocks while reducing the level of emission during the explosion of toxic gases.

Explosive blasting of rock overburden and minerals is as follows. By mining and geological conditions determine the location of wells or holes and produce drilling. Pre-crushed coal of a given fractional composition in a volume of from 2 to 50%, depending on the type of explosives and the resistance of the array, together with the addition of liquid petroleum products in a volume of 1-4%, are mixed with explosives or ammonium nitrate in stationary or mobile units. At the same time, for the explosion of strong rocks, coal powder is introduced into the explosives with a size of fractions from 3˙10 ^-5 to 1˙10 ^-3 m and in a volume of 2 to 20%, depending on the type of explosive and explosive, and when blown up, medium and weak together with finely dispersed coal, coal powder is introduced with particle sizes from 1˙10 ^-3 to 3˙10 ^-3 m to 50% by volume together with finely divided filler, in accordance with the location and type of explosive charge relative to the mineral, structural-strength indicators of the host rocks and the depth of the wells. Blasting of wells is carried out in the usual way.

 At the VostNII stand, tests of explosive mixtures with coal filler prepared in accordance with the proposed method were carried out. The test results are shown in table.6.

 As follows from table 6, the application of the invention allows to increase the efficiency of the explosion while reducing the consumption of explosives and a significant reduction in the level of emission of toxic gases. This confirms the possibility of achieving the above technical result.

 The method of explosive blasting of rock overburden and minerals can be most effectively used in coal mining in deposits developed by open pit mining.

Claims (4)

1. The method of explosive breaking rock overburden and minerals, including drilling wells, loading them with explosives, characterized in that the powder is injected into the explosive and liquid petroleum products are introduced in a volume of 1-4% and coal powder is injected in a volume of 2-20 % with fractions from 3 · 10 ^{- 5} to 1 · 10 ^{- 3} m in size. 2. The method of explosive blasting of rock overburden and minerals, including drilling wells, loading them with explosives, characterized in that coal powder is introduced into the explosive and liquid petroleum products are introduced in a volume of 1-4% and coal powder is introduced in a volume of 2-20 % with fractions from 3 · 10 ^{- 5} to 1 · 10 ^{- 3} m in volume, up to 30% with fractions from 1 · 10 ^{- 3} to 3 · 10 ^{- 3} m.  3. The method according to p. 1 or 2, characterized in that the explosive is injected with coal powder with a vitrinite content of from 75 to 99 wt.  4. The method according to claim 1 or 2, characterized in that ammonium nitrate is used as the explosive.

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