RU91411U1 - EXPLOSIVE CHARGE FOR BLOCK EXPLOSION - Google Patents

Abstract

1. The charge of the explosive composition for blasting, comprising a well, explosive and initiating means, characterized in that it is made in the form of a continuous column of explosive composition with a diameter equal to one or more intermediate detonators placed on a detonating cord along the charge column; while the explosive composition contains a mixture of explosives based on porous ammonium nitrate and expanded perlite sand in a ratio of from 9: 1 to 1: 9 in volume, where! dз is the diameter of the charge, m; ! dc — well diameter, m; ! ρз - loading density, kg / m3; ! ρвс - density of explosive composition, kg / m3. ! 2. The charge according to claim 1, characterized in that moisturizing additives can be introduced into the explosive composition during the loading of the wells. ! 3. The charge according to claim 1, characterized in that it further comprises a polymer sleeve.

Description

The utility model relates to the production of blasting, namely, explosive charges for blasting holes and bore holes to obtain specified excavation contours without significantly breaking the continuity of the rock mass outside the design profile.

Contour blasting allows avoiding disturbance of the rock mass of rocks outside the design contour, providing steeper and more stable slopes of the ledges and excavations, reducing the laboriousness of work to eject the bases and slopes, and increasing the stability of the contour mass. In contour explosions, close wells are drilled along the design boundary of a given recess, in which a dispersed explosive (explosive) charge with a reduced loading density is placed. In the explosion of contour wells, a spalling (shielding) gap is formed. Contour charges usually explode before the explosion of charges of loosening or in the same series with them ahead of 50-100 ms. The blasting method is called the pre-slotting method. The shock waves of the charges of loosening are quenched by a spall gap and the destructive effect of the charge deep into the array is reduced. The depth of the contour wells is generally equal to the depth of the loosening wells, or to obtain more accurate excavation contours, the contour wells are drilled somewhat deeper than the loosening wells.

Known downhole contour charge, consisting of separate sections, separated from each other by means of clamps, which are used as rings of elastic material - rubber (1). Known circuit charge, the dispersion of which is made in the form of a garland of explosive cartridges (2). Each garland cartridge is tied to a detonating cord and twine, the garland of cartridges is lowered into the well along its axis on the twine, the end of which is tied to a wooden rail laid across the well above the wellhead.

A known charge is formed from the bottom of the well in the form of a garland in a single polymer sleeve, the individual cylindrical elements of which are spaced at the same distance from each other and formed by pinching the sleeve (3), adopted by the authors as a prototype. The disadvantages of these charges are the complexity and complexity of forming a garland of a contour charge when using high-density explosives - ammonite 6ЖВ, grammonite 79/21, etc.

The accuracy of contour blasting depends on the explosive power, charge density, distance between charges and charge design. The loading density of contour wells for medium density explosives is maintained at 50-200 kg / m ³ . Wells of the pre-contour (buffer) series also have a reduced loading density - 350-550 kg / m ³ .

It is practically impossible to form a continuous core charge with such a loading density at an explosive density of 850-1050 kg / m ³ with a borehole diameter of 100-250 mm, therefore, such contour wells are charged with dispersed charges from individual cartridges with a diameter of 32-90 mm, which inhibits the mechanization of blasting significantly increases their complexity. In this regard, attempts were made to develop bulk explosives with a low bulk density close to the loading density required for contour blasting, and balanced in terms of oxygen balance. As density reducers low-density substances with a bulk density in the range of 20-80 kg / m ³ , with a small particle size compatible with the main components of standard explosives (ammonium nitrate, liquid and solid combustibles), the properties of which would make it possible to produce explosive compositions, should be used for loading contour wells at blasting sites, including using existing charging and mixing-charging machines. Explosives are known, consisting of ammonium nitrate, diesel fuel, a low-density filler in the form of granules of expanded polystyrene, which may additionally contain pianuric acid, surface-active substances, water, and ethylene glycol solutions (4-7). The disadvantage of these explosives is the need to create production facilities for the production of expanded polystyrene; difficulties in obtaining oxygen-balanced explosives with stable detonation characteristics in the field of bulk densities of 100-300 kg / m ³ .

The technical task of creating a utility model is to increase the efficiency of contour blasting of borehole and borehole charges by reducing the complexity and cost of blasting, using existing means of mechanization, increasing the reliability of initiation and completeness of explosive transformation of an explosive composition.

The technical problem was solved by developing the design of the charge of the explosive composition for blasting, including the explosive and the means of initiation, placed in the shell, which is made in the form of a solid column of explosive composition with a diameter of (d _z ) equal in a shell of a polymer sleeve with one or more intermediate detonators placed on a detonating cord along the charge column, while the explosive composition contains a mixture of explosive based on porous ammonium nitrate and expanded perlite sand in a ratio of 9: 1 to 1: 9 by volume, Where:

d _with - well diameter, m;

ρ _z - loading density, kg / m ³ ;

ρ _sun - the density of the explosive composition, kg / m ³ .

As a polymer sleeve, polyamide, polypropylene, polyethylene single or multi-layer sleeves can be used. To increase strength and elasticity, polyamide hoses can be pre-aged in water.

As explosives, granular and powder explosives based on low-density porous ammonium nitrate are used, which have high detonation ability at a low critical detonation diameter in an open charge. To prevent dusting, delamination of the explosive composition, and to prevent the formation of charges of static electricity, moisturizing additives can be additionally introduced during the loading of wells.

Expanded perlite sand with a bulk density of 30 to 75 kg / m ^{3 is} used as a low-density filler. It is biologically resistant, inert, non-combustible. The particle size of the expanded perlite sand 0.16-0.25 mm allows you to get physically stable explosive compositions that are not stratified in the process of loading wells. Low-density porous ammonium nitrate and low-density expanded perlite sand produce an explosive composition with a density of 100-780 kg / m ³ , which ensures the formation of a continuous column of a contour charge, rather than a garland consisting of separate sections.

The proposed charge for loop blasting (FIGS. 1, 2) is a solid column of explosive composition 1 filling a well 2 for a full section (FIG. 1) or a solid column of charge 3 of explosive composition 1 in a polymer sleeve 4 with an annular gap 5 between charge 3 in the polymer sleeve 4 and the walls of the well 2 (figure 2). Intermediate detonators 6 are placed on the detonating cord 7 along the charge column. The lower end 8 of the polymer sleeve 4 before lowering it into the well 2 is hermetically sealed by any known method. The unfilled upper part of the polymer sleeve 9 is fixed above the wellhead by any known method. In accordance with the design of the blast, the upper uncharged part of the well is clogged with inert material 10; blasting of contour wells without clogging is allowed. The supply of explosive composition into the well is carried out using any known devices 11 installed at the wellhead and providing centering of the charge along the axis of the well.

The proposed charges are formed from explosive compositions consisting of a mixture of explosives based on porous ammonium nitrate and expanded perlite sand in a ratio of 9: 1 to 1: 9 by volume, having a density of 780 to 100 kg / depending on the volumetric content of expanded perlite sand m ³ . Figure 3 shows changes in the density of the explosive composition from the volumetric content of expanded perlite sand with a bulk density of 30, 40 and 75 kg / m ³ (1-75 kg / m ³ , 2-40 kg / m ³ , 3-30 kg / m ³ ). As follows from the data of figure 3, the density of the explosive composition depends on the density of expanded perlite sand, its volumetric content. Figure 4 shows the relationship between the ratio of the diameter of the charge to the diameter of the well (dz / dc) on the density of the explosive composition (ρ _sun ) for different loading densities (ρz) of the contour wells (curves 1, 2, 3, 4 for the loading densities of the contour wells 50, 100, 150, 200 kg / m ^3, respectively). A continuous column of charge over the full cross section of the well (dз / dc = 1) is achieved when the charge densities and explosive composition are equal. By changing the ratio of loading densities and explosive composition (p _s / ρ _sun ) the size of the annular gap between the charge and the walls of the well is regulated.

The main advantages of the claimed explosive charge for blasting contour wells:

- the possibility of forming a continuous column of charge of different diameters, which allows mechanized loading of wells with existing, charging and mixing-charging machines, reduce cost and increase productivity of blasting operations;

- the use of intermediate detonators placed on a detonating cord along the charge column ensures unreliable initiation and completeness of the explosive transformation of the explosive composition;

- the use of low-density explosive composition provides the formation of a continuous column of explosive composition.

Examples of the utility model:

The diameter of the contour wells for ejecting the sides of the quarry is d _c = 0.25 m. The loading density of the wells required by the blasting project is d _s = 100 kg / m ³ .

Example No. 1.

The explosive composition is taken with a density ρ _vs = 250 kg / m ³ , the critical diameter of the detonation in an open charge d _cr. = 100 mm. It contains (by volume) 20% explosives based on porous ammonium nitrate with a density of 780 kg / m ³ and 80% expanded pearlite sand with a bulk density of 75 kg / m ³ . The contour charge is performed in the form of a solid column with a diameter of 0.16 m in a polymer sleeve with 4 intermediate detonators placed on a detonating cord (loading density is less than the density of the explosive composition). Since d _z = 0.16 m exceeds the critical diameter of the detonation of the explosive composition in an open charge (d _cr. = 100 mm), failure-free detonation of the contour charge of the explosive composition will be ensured.

Example No. 2.

The explosive composition is taken with a density ρ _vs = 100 kg / m ³ , the critical diameter of the detonation in an open charge d _cr. = 180 mm. It contains (by volume) 10% explosives based on porous ammonium nitrate with a density of 780 kg / m ³ and 90% expanded pearlite sand with a bulk density of 30 kg / m ³ . The contour charge is performed in the form of a continuous column over a full section of the well (0.25 m in diameter) with 4 intermediate detonators placed on a detonating cord (charge density is equal to the density of the explosive composition). Since d _z = 0.25 m exceeds the critical diameter of the detonation of the explosive composition in an open charge (d _cr. = 180 mm), it will ensure failure-free detonation of the contour charge of the explosive composition.

The main technical result of the utility model - increasing the efficiency of blasting - is achieved due to the distinguishing features of the design of the explosive charge:

- mechanized loading of wells with existing charging and mixing-charging machines due to the formation of a continuous column of contour charge;

- reducing the complexity of the cost of blasting for the formation of a continuous column of a borehole charge of an explosive composition of low density;

- improving the reliability of initiation of the borehole charge and ensuring the completeness of the explosive transformation of the explosive composition through the use of intermediate detonators placed on a detonating cord along the charge column, the use of low-density explosive composition.

The proposed design of the explosive charge was tested during blasting in rocks of various strengths and fractures when setting non-working sides of quarries in extreme condition.

Information sources:

1. USSR Copyright Certificate No. 199729.

2. Technical rules for blasting on the surface, "Nedra", M., 1972.

3. RF patent No. 2404755.

4. RF patent No. 2102367.

5. RF patent No. 2063946.

6. USSR author's certificate No. 1601972.

7. Mechanical mixtures of grammonites with polystyrene foam - “FP” compounds. Technical specifications TU 48 YAASSR 46-22-79.

Claims (3)

1. The charge of the explosive composition for blasting, comprising a well, explosive and means of initiation, characterized in that it is made in the form of a continuous column of explosive composition with a diameter equal to

, with one or more intermediate detonators placed on a detonating cord along the charge column; wherein the explosive composition contains a mixture of explosives based on porous ammonium nitrate and expanded perlite sand in a ratio of 9: 1 to 1: 9 by volume, where d _z - diameter of the charge, m; d _c - well diameter, m; ρ _z - loading density, kg / m ³ ; ρ _sun - the density of the explosive composition, kg / m ³ . 2. The charge according to claim 1, characterized in that moisturizing additives can be introduced into the explosive composition during the loading of the wells. 3. The charge according to claim 1, characterized in that it further comprises a polymer sleeve.