RU65644U1 - EXPLOSIVE CHARGE FOR WATERFILLED WELLS - Google Patents

Abstract

The utility model relates to blasting with borehole charges and can be used in the mining industry for breaking rocks. The essence of the utility model: a charge of bulk explosives in a waterlogged well is formed of two sections: the lower part of the charge is made of a waterproof explosive, the height of which is determined by the specified height of the water gap and the water cut of the well and is calculated by the ratio given in the description of the invention, and the upper section, located above the water gap, - nevodoustoychivogo of explosive having a density less than 1000 kg / m ³ in the polymeric sleeve of diameter greater than the diameter of the borehole utility model n It seeks to increase the technical and economic efficiency of blasting by reducing costs and increasing efficiency explosion, uniformity of crushing of rocks, reliability and safety of blasting in flooded conditions using bulk non-waterproof explosives. 1 head p. of the formula, 1 FIG.

Description

The utility model relates to a method of blasting borehole charges and can be used in the mining industry for breaking rocks.

The search for rational charge designs in crushing rocks by an explosion is defined as the need to increase efficiency explosion, as well as the needs of the practice of blasting in relation to the variety of mining and geological conditions of occurrence of mineral deposits. The use of new charge structures in industrial conditions allows to increase the duration of the impact of explosion products on the walls of the charging chamber and thereby improve the degree of crushing of rocks due to changes in the internal gas dynamics of expanding detonation products.

To efficiently explode a rock mass in conditions of water cut, charges with water gaps were proposed. The location of the water gap in the charge column depends on the degree of water cut in the wells, which is determined by the mass and properties of the explosives that make up the charge in the water well.

Known borehole charge of explosives in the form of separate sections separated by fluid gaps, the installation of fighters, initiation tools, clogging of the upper part of the well with inert material (1). The disadvantage of the charge is that it does not take into account the actual water content of the charged wells, liquid gaps can be created artificially by supplying liquid containers to the well.

A known charge is when a waterproof explosive is poured into the flooded part of the well, the upper portion of the charge is made of a non-waterproof explosive and is separated from the water gap by a float of light material, e.g., polystyrene foam with a minimum bulk density (2). The disadvantage of this charge is the difficulty of finding an effective material, design and parameters of the float, providing its unsinkability under the influence of the weight of the column of the upper portion of the charge and jamming.

The closest known technical solutions to the claimed invention is a method of forming a charge, when a waterproof explosive substance is poured into the flooded part of the well, a powder explosive substance, for example ammonite No. 6ZHV, is poured onto the upper plane of the water gap, which creates a “plug” and locks (“locks” ) the water gap, the length of which decreases over time as the explosive gets wet and sags to a certain level, the upper section is formed from non-water sustainable explosive igdanite (3), adopted by the authors as a prototype. The disadvantage of the prototype method is the increased cost of blasting due to the use of powdered ammonite No. 6ZHV, the mass of which depends on the height of the water gap and the time the well was in charge before the explosion, possible failure of the explosion of a non-waterproof explosive due to jamming of powdered ammonite and the consequences, related to their liquidation.

An object of the invention is to increase the technical and economic efficiency of blasting by reducing cost and increasing efficiency explosion, uniform crushing of rocks, reliability and safety of blasting in flooded conditions using non-waterproof explosives.

The technical problem was solved by the development of a method of generating a charge of explosives in a waterlogged well, including the fixed placement of separate sections of explosives in the well on the surface of the water gap, installation of fighters, initiation tools, clogging of the upper part of the well with an inert material, in which the lower part of the charge is formed from loose granular or powdery waterproof explosive having free intergranular porosity (voidness), the height of which The horn is determined by the height of a given water gap and the water cut of the well and is calculated from the following ratio:

l = (H-h _ave. ) / (l-ρ _cc / ρ _gr ), m;

where: l is the height of the lower portion of the explosive charge, m;

N - the height of the water column in the well, m;

h _ave - the height of the water gap, m;

ρ _centuries , ρ _gr. - the density of the explosive of the lower portion of the charge and the density of its granules, kg / m ³ ;

and the upper portion of the charge is placed above the water gap in a polymer sleeve with a diameter greater than the diameter of the well of a loose non-water-resistant explosive with a density of less than 1000 kg / m ³ .

As explosives of the lower part of the charge can be used loose waterproof granular explosives, for example granulotol, alumotol, granipor, granitol, or powdered, for example hexonite, or explosives of a special composition of granular or powder particles, for example hexonite BP.

A diagram of a charge of explosives with a water gap is shown in figure 1.

Designations:

1 - water gap;

2 - lower (flooded) section of the charge of a waterproof explosive;

3 - the upper portion of the charge of non-waterproof explosive;

4 - inert material of stemming;

5 - polymer sleeve;

6 - well;

D is the diameter of the well;

l is the height of the lower portion of the charge of a waterproof explosive;

l _cc - the height of the upper portion of the charge nevodoustoychivogo explosive;

l _s - stemming height;

L is the depth of the well;

h _ave - the height of the water gap.

The charge for flooded wells is calculated according to the following scheme: in accordance with the design of the explosion, types of industrial explosives (waterproof and non-waterproof) are selected, depending on the water cut of the wells (the height of the water column in the well) and the conditions for blasting, the height of the water gap and the proposed the formula calculates the height of the lower portion of the charge. The height of the column of the borehole charge, the height of the bottom hole is set depending on the type of blasted rock and the technical requirements for blasted rock.

Charges form in the process of separate loading of wells. Waterproof explosive is loaded into the well at its full cross section.

The displaced well water forms a water gap above the upper end of the lower charge. When using granular explosives, part of the well’s water is spent filling voids between the granules of the explosive. The upper portion of the explosive charge is formed in the polymer sleeve also in the process of loading wells. The lower end of the sleeve is placed on the surface of the water gap and filled with explosive with a density of less than 1000 kg / m ³ for the entire section of the well in the direction from the bottom up. The polymer sleeve due to lateral expansion and friction forces is pressed against the walls of the well. This eliminates the longitudinal movement of the polymer sleeve in the well and thereby prevents breakouts of the polymer sleeve and preserves the waterproofing of the non-water-resistant explosive in it. The upper portion of the charge retains its original position and is kept afloat (“closes” the water gap) due to the use of the upper portion of the charge of explosives with a density less than the density of water and tight contact of the polymer sleeve and the walls of the well as a polymer sleeve. The formation of a borehole charge according to the proposed method does not require preliminary drainage of low- and medium-flooded wells.

The water gap created in the charge allows you to disperse the charge into two parts and use the effect of interference of the stress waves generated by the explosion of various parts of the charge. When a charge explodes with a water gap, a shock wave propagates through the water, the energy loss in which is minimal during its movement. At the interface between the two environments “water - explosion products” from different explosives, pressure, density, speed have different values. Two shock waves propagate across the water gap from the lower and upper sections of the charge, moving towards each other, in the collision of which two reflected detonation waves are formed, moving in the opposite directions. Local increase in pressure in the water gap leads to a kind of hydraulic shock. At the junction of the interaction of rarefaction waves in the axial and radial directions, cavitation regions are formed that limit the movement of water in the axial direction. Due to the shock wave of detonation products of explosives, a hydroflow is created from the water gap. Due to counter-directed shock waves, an instantaneous compression of the water gap occurs with a simultaneous increase in the density and temperature of the water. As a result of this, the water passes into a vapor-gas state (vapor-gas) and, expanding, acts by its partial pressure on the adjacent walls

wells. Combined gas due to the high partial pressure, the effect of wedging penetrates into the cracks of the rock mass and thereby more intensive crushing of the rock is achieved.

In the claimed charge when using the water gap, the dust suppression effect is realized due to the wetting of the dusty particles of the blasted rock with steam condensate, their coagulation and gravimetric deposition at an earlier stage of the expansion of the blasted rock. A dust cloud with a large number of small vapor-weighted dust particles of rock falls over the blasting site and does not pollute the surrounding area.

Water neutralizes toxic gases generated during the explosion of an explosive with a negative oxygen balance. Nitrogen and carbon oxides interact with water to form a liquid phase, which also precipitates above the explosion site, preventing the spread of toxic products in the form of gaseous clouds and acid rain outside the danger zone during the explosion.

When using a water gap and a metal-containing explosive in the chemical interaction of a metal (aluminum, etc.), water from the water gap takes part, which acts as an oxidizing agent in relation to the metal.

The use of charges consisting of explosives with different energy characteristics is effective, because allows you to ensure the rational consumption of various in their properties and cost of explosives and optimize the cost of blasting. The increase in the efficiency of rock crushing is achieved due to the repeated exposure of the explosion products to the rock mass to be destroyed, the increase in the time of their active impact on the well walls along the height of the rock ledge before the well is depressurized. In this case, the maximum increase in the duration of the explosion pulse is observed in the lower part of the ledge, i.e. at the site of the most energy-intensive destruction.

An example implementation of the proposed utility model (based on figure 1).

A downhole charge with a diameter of 160 mm at a well depth of L = 10 m, a water cut level of H = 3 m, a water gap height of h _ave = 2 m is formed from a waterproof explosive, for example granulotol GOST 25857-83 (density ρ _cc = 950 kg / m ³ , the density of the granules ρ _gr. = 1500 kg / m ³ ) and non-water-resistant explosive, for example granulite RP with a density of 800 kg / m ³ .

The height of the lower portion of the charge, calculated by the proposed ratio, is.

l = (H-h _ave. ) / (l-ρ _cc / ρ _gr ) = (3-2) / (l-950/1500) = 2.7 m;

The polymer sleeve is lowered to the surface of the water gap and filled with granulite RP. Above the water gap, a non-waterproof RP granulite with a column height of 2.3 m is placed in the polymer sleeve (in accordance with the explosion design). The remaining free part of the polymer sleeve is filled with an inert stem of 3.0 m in length. As the polymer sleeve with a diameter larger than the borehole diameter is filled with explosive and the inert stem is filled, the polymer sleeve is expanded over the entire cross section of the well and is held on the upper plane of the water gap due to adhesion forces to the walls of the well .

The installation of fighters, means of initiation, stemming of wells and initiation of charges was carried out by a method generally accepted in industrial practice.

The technical result of the utility model and the advantages of the proposed explosive charge in a waterlogged well are:

- reducing the cost of blasting by reducing the cost of drainage wells; partial replacement of expensive waterproof explosives with cheaper non-waterproof explosives;

- expansion of the area of use of dispersed charges - in wells of varying degrees of water cut;

- increased explosion efficiency due to the formation of cavitation areas in the axial and radial directions, a wedging effect, later depressurization of wells during an explosion due to the blocking effect created by the water gap;

- increasing the uniformity of crushing of the rock by reducing the maximum pressure and temperature of the explosion products, increasing the weighted average pressure and time of action of the explosion products on the rock mass;

- improving the environmental cleanliness of drilling and blasting operations by neutralizing toxic gases from explosion products, suppressing dust generated during rock destruction, limiting the size of the dust and gas cloud within the explosion hazard zone;

The proposed charge was tested on wells of various diameters and degrees of water cut, in rocks of various strengths.

Drilling and blasting operations using the proposed charge of waterproof and non-waterproof explosives separated by water

interval, allowed to reduce the cost of blasting by reducing the cost of drainage of wells, to increase the uniformity and intensity of crushing of rocks by increasing the yield of conditioned and reducing oversized fractions by 12-15%, to increase the yield of rock mass from 1 borehole to 4 -5%, to improve the study of the soles of the ledge, which allowed to increase the productivity of handling and crushing and screening equipment; improve the environmental situation in the area of the mass explosions, reducing the time of dispersal in the atmosphere of a dust and gas cloud.

Information sources:

1 RF Patent No. 2260770.

2 Yumatov B.P., Shebarshov A.A., Vlasov.V.M. "Experimental studies of the design of the" floating charge ", Sat. "Explosive business", No. 74/31 M., Nedra, 1974.

3 Kovtun I.N., Vorobyov V.D., Dauetas A.A., Duganov B.G. “The effect of water gaps in borehole charges using igdanite on the quality of limestone crushing”, collection of articles "Explosive business", No. 81/38, M., "Nedra", 1979.

Claims (2)

1. The explosive charge for flooded wells, including the fixed placement in the well of individual sections of explosives on the surface of the water gap, the installation of fighters, initiation tools, clogging of the upper part of the well with inert material, characterized in that the lower portion of the charge is formed from a waterproof explosive, height which is determined by the specified height of the water gap and the water cut of the well and is calculated from the following ratio: l = (H-h _ave. ) / (l-ρ _cc / ρ _gr ), m, where l is the height of the lower portion of the explosive charge, m; N - the height of the water column in the well, m; h _ave - the height of the water gap, m; ρ _centuries , ρ _gr. - the density of the explosive of the lower portion of the charge and the density of its granules, kg / m ³ , and the upper portion of the charge is placed above the water gap in a polymer sleeve with a diameter greater than the diameter of the well of non-water-resistant explosive with a density of less than 1000 kg / m ³ . 2. The charge according to claim 1, characterized in that as the explosive of the lower portion of the charge using waterproof granular granular or powder explosives having free intergranular porosity (voidness).