RU132884U1 - EXPLOSIVE CHARGE FOR WATERFILLED WELLS - Google Patents

Abstract

1. The explosive charge for flooded wells, including explosive, blasting means and rings in a waterproof polymer shell, characterized in that it further comprises a clogging of inert material, as rings contains rings of high-density material with an outer diameter equal to the diameter of the explosive charge substances, and an internal diameter of at least a critical diameter of the detonation of the explosive charge, the channel of which is filled with explosive, the rings are placed in the explosive stve equidistant from each other; as an explosive, it contains an intermediate detonator with a primary initiating means mounted above the ring at the top of the charge. 2. The charge according to claim 1, characterized in that the ring is made in the form of a solid monolithic structure of sand-cement, asbestos-cement or concrete mixture or metal.

Description

The utility model relates to the field of blasting and can be used in various industries that use blasting in flooded rock masses.

Ammonium nitrate explosives, having a number of advantages in sensitivity to mechanical stress, possessing a wide range of physicochemical and detonation characteristics, do not have the necessary water resistance. Charging flooded wells with cheap ammonium nitrate explosives is very economically viable. Search and development of rational designs of borehole charges from them for loading waterlogged wells is a very urgent problem. The most promising are explosive charges in polymer arms, installed with some clearance relative to the walls of the well along the entire charge height.

A known charge for flooded wells, consisting of two different types of explosive hose charges with different detonation velocities: one explosive is placed vertically along the axis of the well in the polymer shell, the second is placed in its polymer shell in a spiral around the first with a vertical step of two turns equal to two well diameters. Linear initiation is performed simultaneously along the entire length of the well with a detonating cord with a 40 g / m sample (1). The disadvantage of the charge is the high complexity and complexity of the formation of the borehole charge, the high consumption of means of initiation (detonating cord).

A known charge for waterlogged wells, the explosive substance of which is placed in an elastic shell, at the plugged end of which there are inlets for well water inside the shell to ensure immersion of a charge with a density less than the density of water in the well; to compensate for the soluble explosive, the charge mass increases 1.05-2.0 times in comparison with the charge mass in a dry well (2). A known charge in a sealed polymer shell, the length of which exceeds the length of the explosive charge placed by at least 1.2 times, at the mining enterprise-consumer, the upper part of the shell is depressurized, followed by a 10-12% ammonium nitrate solution concentration of at least 20% ( 3). The disadvantage of these charges is the increased consumption of explosives.

A charge is known, including a non-waterproof explosive in a cylindrical waterproof shell longer than the explosive charge installed on the bottom of a water-filled well; the explosive is covered by a layer of thermoplastic material, which is covered with crushed stone ballast from above to impart negative buoyancy of the explosive charge (4,). A modernized analogue of this charge is known: in a cylindrical shell there is a socket for a fuse, hermetically isolated from the explosive charge, closed with a cover in the form of a sleeve that does not extend outside the outer cylindrical shell, a hole for the fuse initiating wire is made in the cylindrical wall of the sleeve (5). The disadvantage of these charges is the high complexity of the preparation of the charge associated with manual operations to install explosives under the thermoplastic layer of sealant and crushed stone ballast.

A known explosive charge placed in a cylindrical metal shell longer than the length of the charge placed on the bottom of a water-filled well, a gas bubble is located in the metal shell from the side of the liquid medium (6). The disadvantage of the charge is the increased cost of the charge due to the need to manufacture a metal case; increased danger of loading wells - hard impacts of a metal casing against stone walls and the bottom of the well can cause premature detonation of explosive when the charge is lowered to the bottom of the well.

Known explosive charge containing explosive based on porous ammonium nitrate, initiating means, placed in two polymer sleeves of different diameters, in the gap between which, filled with liquid, one or more centering rings with a thickness equal to the width of the liquid gap are installed along the charge height; initiation is carried out by electric or non-electric detonators or an intermediate detonator in the form of a cartridge made of granular explosive, injection or pressed pieces with a diameter less than the diameter of the charge, or in the form of a layer of explosive with a diameter equal to the diameter of the charge, sensitive to the pulse of the primary means of initiation (7), adopted sponsored as a prototype. The disadvantage of the prototype charge is the high complexity, the complexity of the installation and fastening of the rings at a given height in the water gap between the polymer arms during the formation of the charge column to ensure negative buoyancy of the explosive charge in the flooded well.

The technical task of creating a utility model was to increase the efficiency of drilling and blasting operations by reducing the complexity of forming an explosive charge column in a flooded well with negative buoyancy, increasing the explosion efficiency and ensuring the failure-free operation of a borehole charge, expanding the use of ammonium nitrate explosives.

The technical problem was solved by developing an explosive charge for waterlogged wells, including an explosive, an explosive, and rings placed in a waterproof polymer shell, which additionally contains an inert material clogging ring, containing rings of high-density material with an outer diameter equal to the diameter of the charge explosive, and an internal diameter of not less than the critical diameter of the detonation of the explosive charge, the channel of which is filled with explosive Twomey, rings placed in the explosive at an equal distance from each other; as an explosive means contains an intermediate detonator with a primary means of initiation mounted above the ring in the upper part of the charge.

The ring (hereinafter referred to as the monolithic ring, the strong ring) is made in the form of a solid monolithic structure made of sand-cement, asbestos-cement or concrete mixture or metal.

As explosives, granular and / or powder explosives based on ammonium nitrate with different densities and detonation velocities are used, which detonate from the pulse of the intermediate detonator.

As an intermediate detonator, trotyl-containing checkers-detonators are used, and the primary means of initiation is a detonating cord or non-electric detonators of instant or delayed action with a shock wave tube.

As the material of the polymer shell, single or multilayer polyamide or polyethylene or polypropylene sleeves are used, the lower end (lower ends) of which are sealed by any known method. When using two polymer sleeves, their diameters are approximately the same, they are inserted into each other, the lower ends are sealed separately or together.

A distinctive feature of the claimed explosive charge is:

- a charge column in the form of a cylinder of variable cross-section of explosive and rings of high-density material, installed at an equal distance from each other along the length of the charge, the channels of which are filled with explosive.

The proposed utility model of explosive charge for waterlogged wells is illustrated in figure 1, which shows the layout of sections of explosives and rings of high-density material.

Designations:

1 - well;

2 - stemming from inert material;

3 - polymer sleeve;

4 - explosives;

5 - strong monolithic ring;

6 - channel monolithic ring;

6 - checker-detonator;

7 - primary means of initiation;

8 - water;

D is the diameter of the charge is the outer diameter of the ring of a high-density inert material (diameter of the polymer sleeve), m;

d is the inner diameter of the solid monolithic ring, m;

L ₃ is the charge length, m;

l is the distance between the rings of high-density inert material, m;

l _B - water level in the well, m.

The explosive charge consists of ammonium nitrate explosive 4 with a density of less than 1000 kg / m ³ , placed in a polymer sleeve 3, the lower end of which is sealed by any known method. In the explosive, along the height of the charge at an equal distance from each other, solid monolithic rings 5 of high-density inert material are installed in an amount that ensures the flooding (negative buoyancy) of the explosive charge during loading of the well by providing an average charge density of more than 1000 kg / m ³ . Channel 6 of ring 5 is filled with explosive 4. The explosive charge column formed in this way is a cylinder of variable cross section, consisting of alternating sections of explosive with diameters D equal to the diameter of the charge (diameter of the polymer sleeve, outer diameter of the solid monolithic ring), and diameters d, equal to the inner diameter of the ring 5. In the upper part of the charge above the ring 5 there is a detonator-checker 7 with the primary means of initiation 8. The height and number of rings, the distance between them taken in accordance with the design of the explosion. The upper part of the well 1, which is not filled with explosive, is filled with inert material of the hammer 2.

The process of loading wells and the formation of a charge column.

The polymer sleeve with a hermetically sealed lower end is fixed by any known method over a charged well. The polymer sleeve is subsequently lowered into the well while the explosive is fed into it. At the calculated height, a ring of high-density inert material is mounted on the explosive layer. An explosive substance supplied to the polymer sleeve also fills the channel of the ring. A sleeve with an explosive substance moves in a well through a column of water under the influence of an explosive mass, a mass of a monolithic ring with a density of more than 1000 kg / m ³ . A strong monolithic ring having a material density much higher than the density of water prevents the polymer sleeve with the explosive from floating up both during the loading of the wells and while the explosive is in the flooded well before the explosion. In the upper part of the explosive above the placement of the last ring, blasting means 6, 7 are installed in a known manner. The upper part of the well that is not charged with explosive is jammed with an inert material 2.

The principle of the borehole charge.

The charge has an average density of more than 1000 kg / m ³ . The rings are located inside the explosive at an equal distance from each other in charge height; the channel of the ring is filled with granular or powder explosive, as a result of which a continuous column of explosive charge of variable cross section is formed. After the detonator is triggered, the detonation of the explosive section located above the upper ring is excited. The detonation front when meeting with a solid monolithic ring changes the angle of inclination of the detonation wave and detonation products. The channel of a solid monolithic ring leads to an artificial narrowing of the passage of the detonation wave and explosion products formed during detonation of an explosive located above the monolithic ring. An explosive substance enclosed within a solid monolithic ring partially detonates with an increased detonation speed and helps to excite and maintain the detonation of the explosive under the ring at a higher speed. The chemical transformation of an explosive is completed in a shorter period of time and is more complete, which increases the efficiency and power of the explosion. The charge formed by alternating sections of explosives of variable cross-section, the installation of strong rings of high-density inert material, allows you to differentially distribute the energy of the explosion along the height of the destroyed ledge. Tight contact of sections of explosives of different diameters forming a continuous column of charge ensures the reliability of the transmission of the detonation pulse between the sections of the charge of variable cross section and the completeness of the detonation of the charge as a whole, which makes it possible to control the stress field in the array, the process of crushing and moving rocks. When a detonation wave passes through a narrowing channel of a strong monolithic ring, the flow of detonation products is reflected from the walls and its bases and the walls of the well and is concentrated in the direction of detonation. The explosive detonation speed is increased, stabilized and maintained at the same level. In this case, the local pressure increases, the outflow of detonation products from the well is delayed. The charge operates in a pulsating mode, creating multiple impulses of mechanical stresses in the surrounding rock, thereby increasing the efficiency of crushing the blasted rock, increasing the explosion efficiency of the proposed charge.

At the same time, due to counter-directed shock waves, water instantly compresses the water of the annular water gap surrounding the charge in the polymer shell, with an increase in its density and temperature. Water turns into a vaporous state. 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.

The loss of mass and energy of the explosive due to the installation of an inert high-density ring is compensated by an increase in the detonation velocity of the explosive charge and its maintenance at a higher level in the detonation direction, by increasing the pressure and time of depressurization of the well.

, где n-число колец.An example of the use of the proposed downhole charge. A downhole charge with a height of L = 10 m and a diameter of D = 0.2 m is made in a polyamide sleeve of ammonium nitrate explosive Granulite RP with a density ρ _BB = 920 kg / m ³ and a critical diameter of detonation of a charge explosive d _{KP.BB =} 0 , 06 m. The charge in the polymer sleeve is placed in a borehole with a depth of 15 m and a diameter of 0.25 m drilled in solid rock. The water level in the well is 5 m. In accordance with the blasting project, monolithic rings from a concrete mixture with an inert material density ρ _CP = 1800 kg / m ³ and a height h = 0.6 are selected to load the explosive into the polymer sleeve and ensure its flooding m, with an outer diameter of D = 0.2 m and an inner diameter of d = 0.1 m. The charge is formed with 3 monolithic rings installed at the same distance 1 = 2.05 m from each other, including from the bottom of the well and bottom end of stemming:

where n is the number of rings.

A charge column is formed in the polymer sleeve in the following sequence (from the bottom of the well): 2.05 m explosive — ring; - 2.05 m explosive - ring; - 2.05 m explosive - ring; - 2.05 m of explosive, inside the upper portion of the explosive above the ring a checker-detonator is installed with the primary means of initiation. The ring channel is filled in the process of loading the well with explosive.

The claimed technical result - improving the efficiency of blasting - is provided by the design of the borehole charge:

- the reliability of the transmission of the detonation pulse, the completeness of the detonation of the charge are ensured by the continuity of the placement of the explosive in the polymer sleeve in the form of a cylinder of variable cross section, tight contact of the ends of the sections of the explosive of different diameters; the concentration of the detonation wave and explosion products in the direction of detonation;

- increasing the efficiency of the explosion is provided due to the pulsating detonation mode of the explosive of a charge of variable cross section, the interaction of the stress waves arising from the explosion of the sections of explosives that make up the charge column;

- reducing the cost of blasting is provided by reducing the complexity, reducing the time and ease of installation of rings when loading wells;

- expanding the range and scope of ammonium nitrate explosives due to the design of the charge, providing the possibility of using non-water-resistant ammonium nitrate explosives with a density of less than 1000 kg / m ³ (less than the density of water) in flooded wells.

Drilling and blasting operations with the proposed explosive charges made it possible to increase the uniformity of rock crushing due to mainly reducing the oversized (lumpy) fraction yield, to improve the working out of the ledge bottom, which allowed to increase the productivity of handling and crushing and screening equipment and reduce the cost of drilling and blasting operations.

A production test of the inventive borehole explosive charge showed its failure-free and reliable operation when crushing rocks in dry, pre-drained, partially and completely flooded wells with a diameter of 0.12-0.25 m and a depth of 20 m.

In the process of conducting explosions of failures and abnormal operation of the proposed explosive charge for waterlogged wells was not recorded.

Information sources

1 RF patent №2449241

2 USSR AS No. 1630440

3 RF patent №2117912

4 RF patent №2224975

5 RF Patent No. 2315262

6 AU USSR No. 1820177

7 RF patent for utility model No. 84962

Claims (2)

1. The explosive charge for flooded wells, including explosive, blasting means and rings in a waterproof polymer shell, characterized in that it further comprises a clogging of inert material, as rings contains rings of high-density material with an outer diameter equal to the diameter of the explosive charge substances, and an internal diameter of at least a critical diameter of the detonation of the explosive charge, the channel of which is filled with explosive, the rings are placed in the explosive stve equidistant from each other; as an explosive means contains an intermediate detonator with a primary means of initiation, mounted above the ring in the upper part of the charge. 2. The charge according to claim 1, characterized in that the ring is made in the form of a solid monolithic structure of sand-cement, asbestos-cement or concrete mixture or metal.

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