RU2304755C1 - Contour deep-hole charge - Google Patents

Abstract

FIELD: blasting operations for production of preset mining extraction contours without a considerable dislocation of the rock mass continuity beyond the rated profile, applicable in mining industry and construction.

SUBSTANCE: the contour deep-hole charge includes formation of a string of elements 1 of explosive 2 and initiation. The string is formed from the deep-hole bottom in single polymeric branch 3 in the form of cylindrical elements 1 of explosives 2 of a similar height and diameter formed by pinch 4 of branch 3 and being spaced at distance l_d=l_e(ρ_ed_ech ²/ρ_echd_dh ²-l) cm, where l_e - the length of the cylindrical element of the string of the contour explosive charge, cm; d_ech - the diameter of the cylindrical element of the string of the contour explosive charge, cm; d_dh - the deep-hole diameter, cm; ρ_e - the explosive density, g/cu. cm; ρ_ech - the density of deep-hole loading by explosive, q/cu. cm. Initiation is effected by detonating cord 8 fastened with one end on the lower end face of last cylindrical element 1 in the bottom section of the explosive passing along the charge column in the form of alternating linear sections 9 between explosive cylindrical elements 1 and binder assemblies 10 of each explosive cylindrical element 1 in diameter.

EFFECT: enhanced efficiency of contour blasting due to simplified method for formation of the contour charge, expanded assortment of the explosive, reduced cost.

7 cl, 1 dwg

Description

The invention relates to the production of blasting to obtain the specified contour of the excavation without significant violation of the continuity of the massif of rocks outside the design profile and can find application in the mining industry and construction.

Contour blasting is intended to limit the detrimental effects of explosions on stored rock masses during mining of excavation pits, escarpment slopes, tunnels and other underground structures. Contour blasting consists of blasting solid or dispersed explosive charges located in nearby wells drilled either directly along the contour or near the contour of the excavation being constructed. In this case, the diameter of the contour charges in order to reduce the destructive effect of the explosion on the rock is taken significantly less than the diameter of the wells in which they are placed, with an air gap between the walls of the well and the explosive charge.

Known designs of hose loop charges of granulotol or water-containing explosives with a density of 1450 kg / m ³ containing granulotol, a thickened aqueous solution of an oxidizing agent and a crosslinking additive in the shells [1, 2]. The disadvantage of these loop charges is the use of granulotol, which is a toxic, expensive explosive with a critical open-charge detonation diameter of 60-80 mm, which prevents the formation of hose loop charges with a linear density of 0.2-0.8 kg / m. Charges with a high linear density can be used in wells with a diameter of more than 250 mm or in wells of a smaller diameter, but in rocks with a strength not lower than 16-20 on the M. M. Protodyakonov scale.

Known borehole contour charge, consisting of cartridges flankly mounted on a wooden liner adjacent to the walls of the well and oriented along the axis of the contour row of charges [3], the disadvantage of which is the complexity and duration of the formation of the contour charge due to the use of wooden inserts to fix the same distance between explosive cartridges, the inability to form a contour charge along the axis of the well.

Known explosive charge, consisting of separate sections, separated from each other by means of clamps, which are used rings of elastic material, such as rubber. These charges are used for the convenience of transportation, the distance between the individual sections is taken so that they can be zigzag stacked in a transport container for transportation [4].

Known dispersed charge for contour blasting, which is a garland of explosive cartridges [5], adopted by the authors as a prototype. Each garland cartridge is tied to a detonating cord and twine, a 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. The disadvantage of the prototype charge is the complexity and high complexity of forming a contour charge garland from standard explosive cartridges, as well as the limited choice of explosive cartridges in diameter and length for wells of various diameters and types of explosives for effective explosive breaking of rocks with different physical and technical characteristics.

An object of the invention is to increase the efficiency of contour blasting by simplifying the method of forming a contour charge, expanding the range of explosives, and reducing cost.

The most important parameters of contour blasting are the loading density of the well, with the help of which the level of compression stresses near the charge is regulated, and the distance between adjacent charges, which affects the efficiency of the addition of tangential stresses. At the same time, the loading density of the well can only be changed if a certain condition is met: the explosive should be concentrated at the axis of the well and should not come into contact with its walls, which reduces the contouring blast effect of the explosion on the protected rock mass. When an explosive is placed at the axis of a well, a shock wave acts on its walls during an explosion, which arises in the air surrounding the explosive charge and the pressure of the explosion products. It is known that the pressure at the front of a shock wave in air is determined by the loading density, the heat of explosion, and the density of the explosive. When an air shock wave approaches a rigid fixed barrier (well wall), the pressure on the well walls as a result of wave reflection increases by about 8 times. To prevent rock crushing and crack formation in the area closest to the well, the magnitude of the shock wave on the well walls should not exceed the temporary compressive strength of the rock. The loading density of the explosive of a contour well is calculated by known methods, depending on the strength characteristics of the rocks in compression, determined experimentally or taken from reference data. The required well loading density for an explosive with a known density depends on the ratio of the diameters of the charge and the well with a continuous core charge; the diameter and length of the cartridge, the distance between the cartridges, the diameter of the well with dispersed loading.

The technical problem was solved by developing a dispersed borehole contour charge, including the formation of a garland of explosive cartridges and initiation means, in which a garland is formed from the bottom of the well in a single polymer sleeve in the form of cylindrical explosive elements of the same height and diameter, formed by pinching the sleeve and spaced from each other at a distance (1p), calculated by the formula:

l _p = l _cc (ρ _cc d _s ² / ρ _s d _c ² -1), cm

Where:

_cc l - length of the cylindrical member garland contour of the explosive charge, cm;

d _s - the diameter of the cylindrical element of the garland of the contour charge BB, cm;

d _c - well diameter, cm;

ρ _centuries - the density of the explosive, g / cm ³ ;

ρ _z - loading density of the well with explosive, g / cm ³ ;

and the initiation is carried out by a detonating cord fixed at one end on the lower end of the last cylindrical element in the bottom of the explosive charge passing along the charge column in the form of alternating linear sections between the cylindrical elements of the explosive and the strapping nodes of each cylindrical element of the explosive in diameter.

As a polymer sleeve, polyethylene, polypropylene, polyamide single or multi-layer sleeves can be used. The ends of the garland are assembled into a “forelock” and sealed with clipping or any other known method. The diameter of the cylindrical element is equal to the diameter of the sleeve.

The invention is illustrated in the drawing, which shows a view of the downhole contour charge.

Downhole loop charge (figure 1) consists of a garland of cylindrical elements 1 of the same height and diameter equal to the diameter of the sleeve (d _s = d _p ), the explosive substance 2 of which is placed in a single polymer sleeve 3. The cylindrical elements 1 in a single polymer sleeve 3 are separated from each other by means of clamps 4, by clipping or in any other known manner, they are separated from each other at a distance of l _centuries. calculated by the proposed formula. The ends of the sleeves are assembled in a “forelock” and sealed by clipping or any known method. The charge is formed from the bottom of the well 7. A garland of cylindrical BB elements is lowered into the well along its axis on the same sleeve, therefore, the polymer sleeve is selected with such tensile (tensile) material strength that it can withstand the mass of the garland cylindrical elements. The upper end of the polymer sleeve 13 is fixed on the rail 12, laid across the well above its mouth. The contour charge is placed along the axis of the well with an air gap of 14 between the cylindrical charge elements and the walls of the well. When a contour charge is formed in wells with a depth of more than 10-15 m, a polymer cord or twine is attached to the bottom of the last cylindrical element in the bottom of the explosive charge, which runs along the charge column and is additionally fixed on several or all cylindrical garland elements by tying them in diameter. In this case, the polymer cord or twine is fixed to the rail together with the polymer sleeve.

The contour charge is initiated by a detonating cord 8 by placing it along the entire column of the borehole charge in the form of linear sections 9 and strapping nodes 10 along the diameter of each cylindrical element.

After lowering the garland of cylindrical BB elements into the well, the upper uncharged part of the well is clogged with inert material 11 in accordance with the explosion design.

The proposed garland of cylindrical elements of a contour charge can be manufactured at mining enterprises having production points for industrial explosives. When loading wells with a high stemming height, the lowering of the charge can be carried out on a twine or a polymer cord fastened with a sleeve of garland above the last cylindrical element in the upper part of the explosive charge, the end of which is fixed on a rail laid across the well above its mouth. By the order of the consumer, garlands for contour charges can be made at the manufacturing enterprises of explosives in the form of cylindrical elements of a given diameter and the estimated distance between them. The formation of a borehole contour charge can be carried out from several sections of a garland connected at the locations of the sleeve between the cylindrical elements of the explosive.

The main advantages of the claimed circuit charge in comparison with the prototype:

- ease of manufacture - filling certain portions of the explosive into a single polymer sleeve with subsequent clamping and fixing the clamping point in any known manner (clipping, dressing with a polymer cord, etc.), which reduces the cost of the contour charge and the cost of blasting in general;

- the possibility of producing contour charges of any diameter, from any explosive, depending on the strength of the rock being exploded and the diameter of the wells;

- ease of loading wells and installing the blast line, which increases the safety of blasting, reduces the complexity, and therefore the cost of blasting;

- the possibility of manufacturing charges directly at the places of blasting, as well as at manufacturing plants of explosives.

The scheme for calculating the parameters of a garland of cylindrical elements of explosive circuit charge for loading wells.

1. For a given type of rock blasted from the experimental data, or a reference defined rock strength characteristics, such as tensile strength rock compressive ([σ] _SJ..).

2. Selects the type of explosive (explosion heat - Q _taken and density - ρ _cc).

3. The diameter (d _h ) and the length of the cylindrical element (l _cc ) of the explosive are selected to form the column of the borehole contour charge.

4. The distance between the cylindrical elements BB (l _p ) is calculated by the proposed formula.

Example No. 1.

Rock - rock with temporary resistance to compression - [σ] compress _. = 900 kgf / cm ² (determined experimentally).

The diameter of the well is 11 cm.

Type BB - ammonite 6ZHV with heat of explosion Q _centuries. = 1000 kcal / kg, density ρ _cb = 0.92 g / cm ³ .

The parameters of the cylindrical element of the garland: diameter d _s = 3.5 cm, length l _cc = 40 cm.

For the specified parameters of the explosive, type of rock, the loading density (ρ _s ) is 0.044 g / cm ³ .

The distance between the cylindrical elements of the explosive with a diameter of 3.5 cm, a length of 40 cm when placed in wells with a diameter of 11 cm, calculated by the proposed formula, is: l _p. = l _cu (ρ _cc d _z ² / ρ _c d _c ² -1) = 40 (0.92 × 3.5 ² / 0.044 × 11 ² -1) = 44.7 cm, while the linear density of the borehole charge is 0.42 kg / m.

The main technical result of the invention is to increase the efficiency of contour blasting is achieved due to the distinguishing features of the design of the contour charge:

- the simplicity of the formation of a contour charge from cylindrical elements makes it possible to produce charges of non-standard sizes at the places of blasting from the explosives available on the quarry, which expands the possibilities of designing drilling and blasting operations;

- the simplicity of the formation of a contour charge at the places of blasting and the ease of installation of the blast network, which reduces the cost of drilling and blasting;

- the use of contour charges made in a single polymer sleeve expands the range of explosives used, reduces the cost of blasting due to the use of cheap ammonium nitrate explosives, to form dispersed contour charges of non-standard sizes.

The proposed design of the borehole contour charge, formed in the form of cylindrical elements in a single polymer sleeve, spaced from each other at a distance calculated by the proposed formula, was tested during blasting in rocks of various strengths and fractures when setting non-working sides of open pits in extreme condition.

Information sources

1. Antonenko A.K., Zateev V.G. "The experience of using special technology for offshoot rocky ledges in the USSR and abroad." Overview information. Series Mining production, Moscow, 1986.

2. RF patent No. 2097680.

3. RF patent No. 2150672.

4. Copyright certificate of the USSR No. 199729.

5. Technical rules for blasting on the surface, "Nedra", Moscow, 1972, pp. 45-47.

Claims (7)

1. Downhole contour charge, including the formation of a garland of explosive elements and initiation, characterized in that the garland is formed from the bottom of the well in a single polymer sleeve in the form of cylindrical explosive elements of the same height and diameter, formed by pinching the sleeve, and spaced from each other by distance (l _p ) calculated by the formula

where l _cc - the length of the cylindrical member garland contour of the explosive charge, cm; d _s - the diameter of the cylindrical element of the garland of the contour charge of explosives, cm; d _c - well diameter, cm; ρ _centuries - the density of the explosive, g / cm ³ ; ρ _z - loading density of the well with explosive, g / cm ³ ; and the initiation is carried out by a detonating cord fixed at one end on the lower end of the last cylindrical element in the bottom of the explosive charge passing along the charge column in the form of alternating linear sections between the cylindrical elements of the explosive and the strapping nodes of each cylindrical element of the explosive in diameter. 2. The charge according to claim 1, characterized in that a polyethylene or polypropylene or polyamide sleeve is taken as a polymer sleeve. 3. The charge according to claim 1, characterized in that the polymeric material of the sleeve is taken single or multi-layer. 4. The charge according to claim 1, characterized in that the ends of the garland are collected in a “forelock” and are closed by clipping or in any known manner. 5. The charge according to claim 1, characterized in that the charge is made up of several garlands of cylindrical elements by connecting them along a polymer sleeve between the cylindrical elements of the explosive. 6. The charge according to claim 1, characterized in that the garland of the charge is lowered into the well on a twine tied to the end of the polymer sleeve of the garland above the last cylindrical element in the upper part of the explosive charge. 7. The charge according to claim 1, characterized in that it further comprises a polymer cord or twine, which runs along the charge column and is fixed on the lower end of the last cylindrical element in the bottom of the explosive charge and is additionally fixed on several or all of the cylindrical BB elements of the garland by their strapping in diameter.