RU83326U1 - EXPLOSIVES CHARGED FOR WATERED DEPARTMENT WELLS - Google Patents

Abstract

1. The explosive charge for flooded upstream wells, including a well, an elastic chamber, an explosive and an initiating means, characterized in that the charge is made of granular ammonium nitrate explosive in a polyamide sleeve with a diameter greater than the diameter of the well and a length not less than the depth of the well with one sealed with an end face and fixed in the well or by one elastic chamber with a diameter not less than the diameter of the well filled with compressed air, placed in a polyamide sleeve at the bottom of the well, or two elastic chambers with diameters of at least the diameter of the well filled with compressed air, one of which is above the explosive inside the polyamide sleeve at the bottom of the well, and the other under the explosive inside or outside the polyamide sleeve, while the granular ammonium nitrate explosive is fed into the polyamide sleeve pneumatically. ! 2. The charge according to claim 1, characterized in that the part of the polyamide sleeve that is not filled with explosive is refilled into the well and used as a stemmer. ! 3. The charge according to claim 1, characterized in that up to 5 wt.% Water is introduced into the granular ammonium nitrate explosive in the process of pneumatic charging. ! 4. The charge according to claim 1, characterized in that the granular ammonium nitrate explosive contains up to 5 wt.% St. 100% powdered thickener, for example guargam or polyacrylamide, or sodium carboxymethyl cellulose. ! 5. The charge according to claim 1, characterized in that two polyamide sleeves are inserted inserted into each other. ! 6. The charge according to claim 1, characterized in that the poly

Description

The utility model relates to mining, namely, explosive charges for explosive flooded wells in underground mining enterprises.

The most widely used in underground rock and ore mining is the technology of pneumatic loading of ascending wells and holes with ammonium nitrate explosives.

However, even in conditions of low rock inflow, the charge of unpatched granular ammonium nitrate explosive during the drilling of holes and boreholes and the installation of the explosive network is completely washed out along cracks, while losing detonation ability.

Known methods for loading ascending wells with ammonium nitrate explosives in the form of separate cartridges, tightly adjacent to each other and held in the well by parachutes, under which self-jamming jamming is installed. Two fighters are usually used - in the upper and lower parts of the charge (1) or by placing individual cartridges in a polyethylene sleeve (2).

The disadvantage of these methods of loading is the high complexity of forming a column of a borehole charge from individual cartridges of small mass and length; the use of such cartridges for loading deep ascending wells is not economically feasible and practically difficult, especially when loading in conditions of high water cut.

A known method of dispersing the column of explosive charge in dry downhole wells into several parts by air gaps. Air gaps in the well are created using a pneumatic shutter, the diameter of which exceeds the diameter of the well. The shutter, consisting of a rubber chamber with a nipple and a connecting pipe with a hollow needle, is lowered into the well on the connecting pipe to a predetermined depth and inflated with air to a predetermined pressure. Then the connecting tube with the needle is separated from the pneumatic shutter and removed from the well, and placed on the shutter

the action movie and part of the explosive dispersed charge (3), adopted by the authors as a prototype.

The technical task of creating a utility model was to increase the efficiency of blasting in flooded uphole wells through the use of a charge of granular ammonium nitrate explosive in waterproofing polymer shells made by pneumatic loading.

The problem was solved by developing an explosive charge for flooded upstream wells, including a well, an elastic chamber, an explosive and an initiating means, which is made of a granular ammonium nitrate explosive in a polyamide sleeve with a diameter greater than the diameter of the well and a length not less than the depth of the well with one end face , and is fixed on the walls of the well or with one elastic chamber with a diameter of at least the diameter of the well filled with compressed air, placed in polyamide the sleeve at the bottom of the well, or with two elastic chambers with diameters of at least the diameter of the well filled with compressed air, one of which is above the explosive inside the polyamide sleeve at the bottom of the well, and the other under the explosive inside or outside the polyamide sleeve, while the granular ammonium nitrate explosive is fed into the polyamide sleeve pneumatically.

The part of the polyamide sleeve that is not filled with explosive is used as the bottom hole of the well, below which another elastic chamber filled with compressed air can be installed to more reliably hold the charge in the ascending well in the presence of rock inflow.

As explosives, granular granular explosives based on granular ammonium nitrate are used.

As sleeves, two polyamide sleeves inserted into each other can be used.

To increase strength and elasticity, polyamide hoses are preliminarily aged in water. In water, not the entire sleeve can be maintained, but only its ends.

During loading, up to 5 wt.% Water is introduced into the explosive composition.

Granular ammonium nitrate explosives may contain up to 5% by weight of a thickener, guargam, polyacrylamide or carboxymethyl cellulose sodium.

The invention is illustrated in FIGS. 1-2.

Figure 1 is a diagram of the explosive charge in a two-layer polyamide sleeve in a flooded ascending well with one elastic chamber located at the bottom of the well in a two-layer polyamide sleeve.

Figure 2 - diagram of the explosive charge in a two-layer polyamide sleeve in a flooded uphole with two elastic chambers, one of which is located in a two-layer polyamide sleeve above the explosive at the bottom of the well, and the second under the explosive:

a) outside the two-layer polyamide sleeve;

b) inside a two-layer polyamide sleeve.

Designations:

1 - flooded ascending well (hole);

2 - a two-layer polyamide sleeve;

3 - an elastic chamber filled with compressed air;

4 - nipple;

5 - explosive;

6 - detonator capsule;

7 - intermediate detonator;

8 - shock wave tube of a non-electric initiation system or detonating cord;

9 - stemming from a two-layer polyamide sleeve;

d - well diameter, mm;

Dp is the diameter of the inner polyamide sleeve, mm.

The elastic chamber is a rubber chamber with a nipple. Air is supplied to the chamber through a needle connected to a compressor or other device by a tube.

Charging wells is as follows. The polyamide sleeve is taken with a diameter (D _p ) greater than the diameter of the well (d), not less than the depth of the well. It is pre-aged in water to give it elasticity and strength. Two polyamide sleeves of approximately equal diameters inserted into each other can be used.

An elastic chamber, into the nipple of which a hollow needle is inserted, connected through a connecting tube with a compressor or other device (not shown in Fig.), Is inserted in a compressed form into a polyamide sleeve 2 with an end face fixed in any way. The prepared assembly is delivered to the wellhead. The elastic chamber 3 through the nipple 4, the hollow needle and the connecting tube is pumped with air to a predetermined pressure sufficient to fix the polyamide sleeve in the flooded uphole. When expanding the elastic chamber 3, the sleeve shell is tightly attached to the walls of the well 1. After that, the connecting tube with the hollow needle is pulled out of the elastic chamber and removed from the polyamide sleeve. In a polyamide sleeve, firmly fastened to the walls of the well with an elastic chamber filled with compressed air, a charging hose with a nozzle is inserted, at the end of which an initiating means is installed (intermediate detonator 7 with a detonator capsule 6 with a shock wave tube or detonating cord 8). An intermediate detonator located at the end of the charging hose is inserted into the polyamide sleeve and held under the elastic chamber 3 by means of a locking device (parachute) of a spacer type. The borehole charge column BB 5 is formed inside the polyamide sleeve during pneumatic loading of the well. The explosive enters the polyamide sleeve and fills it into the full section of the well with the simultaneous withdrawal of the charging hose from the polyamide sleeve. To impart plastic properties of explosives, up to 5 wt.% Water is supplied to the charging hose during pneumatic charging. When moistening the granules of ammonium nitrate, the explosive is densified in the polyamide sleeve and its adhesion to the surface of the polyamide sleeve increases, which prevents the explosive from spilling out of the well. The part of the polyamide sleeve that is not filled with explosive is used as the face 9. It is allowed to install the second elastic chamber 3 at the bottom of the well under the explosive inside the polyamide sleeve (Fig.2b) or outside it (Fig.2a). The diameter of the polyamide sleeve is larger than the diameter of the well (Dp> d), therefore, it is tightly pressed against the walls of the well along the entire perimeter under the action of compressed air and explosive pressure, and due to the adhesion forces between the polyamide sleeve and the walls of the well, it is additionally held on it by the lateral effect the spread of explosives. The elastic chamber not only contributes to the retention of explosive charge in the well, but also

prevents the flow of water from the surrounding massif between the explosive charge in the polyamide sleeve and the walls of the well.

To prevent the leaching of ammonium nitrate when the polyamide sleeve is torn on the well walls, explosives containing up to 5 wt. 100% powdered thickener (guargam, polyacrylamide, sodium carboxymethyl cellulose). The thickener swells in the presence of water, turning into a gel, which plugs the tears of the polyamide sleeve, which are formed when it comes into contact with irregularities in the walls of the well, and this prevents the penetration of water into the polyamide sleeve and leaching of ammonium nitrate.

The main advantages of the claimed charge:

- the possibility of manufacturing charges in waterproofing polyamide sleeves from non-waterproof granular ammonium nitrate explosives by pneumatic loading of flooded upstream wells;

- the ability to use the same equipment for the manufacture of charges pneumatically in both dry and flooded ascending wells.

An example implementation of the invention (figure 1).

The charge is formed in ascending irrigated fan wells with a depth of 20 to 40 m with a diameter of 102 mm and is carried out using a polyamide two-layer sleeve with a film thickness of 50 μm with a diameter of 115 mm. As an elastic chamber, a spherical rubber chamber with a nipple built into it is used. Compressed air with a final pressure of 2.1 kg / cm ² is supplied into the elastic chamber through a rubber hose, which provides tight pressing of the sleeve to the walls of the well and reliable holding of the explosive charge in the polyamide sleeve during pneumatic charging. The blasting project provides for the reverse initiation of the explosive charge column with the installation of an intermediate detonator at the bottom of the well inside the polyamide sleeve. Grammotol-20 explosive (TU 7276-016-11692478-98) is fed into the wells using an Ulba-400 air charger through a 40 mm diameter hose. As a means of detonation, a DAP detonator with a mass of 300 g is used, initiated by a non-electric detonator with a shock wave tube of the SINV system. A detonator block mounted on the end of the charging hose is inserted

inside the polyamide sleeve. The charge density of the explosive at 5% water supply was 1.05-1.10 g / cm ³ . The mass of explosives in the wells is from 60 to 160 kg, depending on the length of the generated charge. Clogging of the uncharged part of the well is carried out by the free part of the sleeve by sealing it with a downhole. The explosive charges formed in the ascending wells in watertight polyamide hoses do not spill out of the wells and provide the necessary waterproofing of the explosive from running water circulating in the rock mass.

The proposed charge provides the claimed technical result - increasing the efficiency of blasting - due to the design of the charge formed in the process of pneumatic charging, which allows blasting with non-water-resistant granular ammonium nitrate explosives in flooded upstream wells.

The proposed explosive charge was tested on flooded ascending wells and holes. Drilling and blasting operations using the proposed explosive charge design allowed to reduce the cost of work through the use of mechanized loading of granular ammonium nitrate granular explosive substances instead of the manual method of generating charge from individual cartridges, to increase labor productivity by 40% and the intensity of rock crushing due to reduced yield oversize by 10-15%.

Information sources

1 EG Baranov, O. Oberemok "Blasting operations in underground mines", M., "Nedra", 1985, pp. 141-142.

2 V.I. Strikachev, N.N. Gaponov, N.R. Shevtsov et al. “Technology of mechanized loading and blocking of wells with advanced torpedoing of hard-roofing roofs in coal mines”, collection of articles Explosive Business, 87/44.

3 RF Patent No. 69630.

4 RF Patent No. 2235971.

Claims (6)

1. The explosive charge for flooded upstream wells, including a well, an elastic chamber, an explosive and an initiating means, characterized in that the charge is made of granular ammonium nitrate explosive in a polyamide sleeve with a diameter greater than the diameter of the well and a length not less than the depth of the well with one sealed with an end face and fixed in the well or by one elastic chamber with a diameter not less than the diameter of the well filled with compressed air, placed in a polyamide sleeve at the bottom of the well, or two elastic chambers with diameters of at least the diameter of the well filled with compressed air, one of which is above the explosive inside the polyamide sleeve at the bottom of the well, and the other under the explosive inside or outside the polyamide sleeve, while the granular ammonium nitrate explosive is fed into the polyamide sleeve pneumatically. 2. The charge according to claim 1, characterized in that the part of the polyamide sleeve that is not filled with explosive is refilled into the well and used as a stemmer. 3. The charge according to claim 1, characterized in that up to 5 wt.% Water is introduced into the granular ammonium nitrate explosive in the process of pneumatic charging. 4. The charge according to claim 1, characterized in that the granular ammonium nitrate explosive contains up to 5 wt.% St. 100% powdered thickener, for example guargam or polyacrylamide, or sodium carboxymethyl cellulose. 5. The charge according to claim 1, characterized in that two polyamide sleeves are inserted inserted into each other. 6. The charge according to claim 1, characterized in that the polyamide sleeve is previously held in water.