RU2160424C1 - Method for charging of flooded wells by water-containing explosive - Google Patents

Abstract

FIELD: mining industry, applicable at blast rock-breaking, sulfide- containing rocks inclusive in crumbing and flooded masses. SUBSTANCE: prior to dipping the hose made of water-proof material in the well, a hole is formed in its lower end part, through which the hose is filled with water of the well at dipping; the hole area is so selected that the volume flow rate of water through it would be at least 0.5 cu.dm/S, and the maximum diameter of the hole would not exceed 0.85 of the well diameter. Whenever necessary, a distance piece is introduced in the hose through the hole, and the linear section of the hose between its end and the lower edge of the distance piece is bent inside the hose. Before placement of the charging hose in the hose or simultaneously with it, the hose may be additionally filled with water through its upper part. Filling of the hose with well water facilitates unimpeded placement of the charge hose inside the hose, its mechanical damage of its sheath exclusive. Full isolation of the charge of water- containing explosive from the bottom and well walls enhances safety of operations at blast ore-breaking. EFFECT: enhanced reliability of charge protection against washing- out by running water and against spreading in cracks of well walls, enhanced efficiency of the process of well charging by water- containing explosive. 3 cl, 11 ex

Description

 The invention relates to the mining industry and can be used for loading wells with water-containing explosives during explosive breaking of ores and rocks, including sulfide-containing, in fractured and flooded massifs.

 Charging flooded wells with water-containing explosives (BB) is fraught with the danger of leaching the charge with running water or spreading the charge along cracks in the walls of the wells. In order to maintain charge integrity, various measures are being taken to isolate the charge from the duct zones and from the walls of the wells. These activities are mainly ineffective or technically difficult to implement.

 A known method of loading wells with a water-containing explosive (see Baron V.L., Kantor V.Kh. Technique and technology of blasting in the USA. - M.: Nedra, 1989, p. 74), which consists in installing special plastic rings localizing zone of running water and preventing water-containing explosives from leaching during its subsequent supply to the well.

 The disadvantages of the method are the need to identify the presence and location of the zones of running water, as well as the technical difficulty of installing special rings. In addition, the method is not applicable for loading flooded wells, the walls of which have lengthwise cracks.

 A known method of loading flooded wells with a water-containing explosive (see US patent N 4055122, M. CL F 42 D 001/00, 1976), comprising placing a metal casing in a well having fractured walls, inside which sections of cardboard pipes are mounted, fastening the joints of the sections with each other, after which they remove the metal casing from the well and fill the space inside the cardboard sections with a water-containing explosive.

 The disadvantage of this method is its low reliability due to the soaking and destruction of cardboard, which makes it impossible to charge wells with running water. In addition, the method is characterized by low productivity, which is associated with the need to lower and remove the metal casing from the well, as well as with the installation of cardboard sections and the fastening of their joints.

 There is also a known method of charging flooded wells with a water-containing explosive using a polyethylene sleeve (see Kutuzov B.N. Priority areas for technical re-equipment of open-pit coal enterprises, building ore to improve explosive technologies. In Sat reports of the VI All-Russian meeting on blasting, Mezhdurechensk , 1997), which consists in the fact that a polyethylene sleeve is put on a special sleeve with an accordion, the lower part of which is sealed, the sleeve is connected to the wheelbarrow nuclear machine and fed into the sleeve of a water-containing explosive, as a result of which the sleeve is pulled together from the sleeve and lowered into a well filled with water.

 The disadvantage of this method is the need to use a complex device and the technical difficulty of implementing the method. In addition, there is a danger of mechanical damage to the polyethylene sleeve when it is pulled from the sleeve, as well as when the sleeve walls are pushed apart under the pressure of a water-containing explosive.

 Closest to the claimed method is a method of loading flooded wells with a water-containing explosive (see Seinov NP, Valiev B. S. Technology of loading flooded wells with non-water-resistant explosives. - in Sat Blasting N 89/46, M .: Nedra , 1986, pp. 204-215), according to which a sleeve made of a waterproof film is immersed in a well, a charging hose is placed inside the sleeve and a water-containing explosive is fed through it.

 The main disadvantage of this method is the increased risk of mechanical damage to the sleeve by the charging hose when it is placed inside the sleeve, the walls of which collapse under the pressure of water. In addition, the operation of placing the charging hose inside the sleeve is quite time-consuming, which reduces the productivity of the charging process.

The present invention is aimed at solving the problem of improving the reliability of the protection of the charge of a water-containing explosive when it is loaded into wells whose walls have cracks and / or zones of flowing water, as well as to increase the productivity of the charging process. The problem is solved in that in a method for loading flooded wells with a water-containing explosive, including immersing a sleeve made of a waterproof material in the well, placing a charging hose inside the sleeve and mechanically supplying a water-containing explosive along it, according to the invention, before the sleeve is immersed in the well in its lower the end part forms a hole through which when immersed in the well, the sleeve is filled with water in the well, while the area of the hole ybirayut such that the volumetric flow rate therethrough was not less than 0.5 ^dm3 / s, and the maximum equivalent diameter of the holes does not exceed 0.85 borehole diameter.

 To solve this problem, it is also directed that a spacer element is introduced through the hole into the sleeve, and the linear portion of the sleeve between its end and the lower edge of the spacer element is bent into the sleeve.

 The solution to this problem also contributes to the fact that before or simultaneously with the placement in the sleeve of the charging hose, the sleeve is additionally filled with water through its upper part.

 The spacer element preferably has a circular cross section, but it can also have another geometric shape, for example oval.

 Preferably, a plastic film or a laminated polypropylene is used as the waterproof material of the sleeve, but other waterproof materials, for example, a polyamide film, can also be used.

The essence of the invention lies in the fact that when a sleeve is immersed in a waterlogged well from a waterproof material, in the lower end part of which a hole is formed, conditions are created for the water in the well to penetrate into the sleeve under the influence of hydrostatic pressure of a water column. If the area of the hole is chosen such that the volumetric flow rate of water through it is at least 0.5 dm ³ / s, and the maximum equivalent diameter of the hole does not exceed 0.85 of the diameter of the well, then when the sleeve is immersed, the edges of its lower end part are not affected by irregularities and sharp edges of cracks in the walls of the well, which contributes to the unimpeded immersion of the sleeve and eliminates its mechanical damage. Water contained in the well, under the influence of hydrostatic pressure, fills the sleeve with high speed, squeezing air out of it in the direction of the wellhead, as a result of which the sleeve quickly sinks into the well while expanding its walls, which creates conditions for the subsequent unhindered placement of the charging hose inside the sleeve . When the sleeve is immersed at the bottom of the bottom of the well, its lower part is crushed, as a result of which the hole is sealed, which ensures complete isolation of the charge from the walls and bottom of the well. The water contained in the sleeve is displaced by the column of the formed charge and, being above its level, plays the role of stemming.

If the maximum equivalent diameter of the hole exceeds 0.85 of the diameter of the well, then the edges of its lower end part are affected by roughness and sharp edges of cracks in the walls of the well, which significantly complicates the immersion of the sleeve into the well until the stop of the immersion. If the area of the hole is chosen such that the volumetric flow rate of water through it is less than 0.5 dm ³ / s, then to fill the sleeve with water in the well, it is necessary to drastically slow down the speed of immersion of the sleeve, which significantly reduces the productivity of the charging process. The increase in the speed of immersion of the sleeve leads to the fact that water, which has not had time to enter the sleeve, squeezes its walls, which greatly complicates the placement of the charging hose inside the sleeve.

 The introduction of a spacer element into the sleeve through the hole and bending of the linear portion of the sleeve between its end and the lower edge of the spacer element into the sleeve contributes to the fact that when the mechanized supply of water-containing explosive material through the charging hose is made, the bent portion of the sleeve is unbent and acts as a check valve, as a result of which the hole still more reliably sealed. The spacer element is simultaneously used as a load.

 Additional filling of the sleeve with water through its upper part facilitates the unhindered placement of a charging hose inside it and increases the amount of water that plays the positive role of stemming.

 The essence of the proposed method and the achieved results can be more clearly illustrated by the following examples of specific performance.

Example 1. Carry out 5 flooded wells with a diameter of 253 mm, a depth of 20 m with a water level of 8-8.5 m water-containing explosives such as aquatol composition, wt.%: Thickened solution of ammonium nitrate - 80, TNT - 20. Wells drilled in fractured rocks . In the lower end part of 5 sleeves made of polyethylene film 21 m long by partially pulling the sleeves with a cord, a hole of 3.63 dm ² with an equivalent diameter of 215 mm is formed and, under the influence of a load of 1 kg, is immersed in the corresponding wells. The sleeves are immersed for 40-45 seconds at a volumetric flow rate of water through the hole of 9.3-9.5 dm ³ / s. In each sleeve, a charging hose is placed alternately and 900 kg of water-containing explosive of the Aquatol type are pumped through it. At the end of charging, the height of the charge column in each well is measured. Measurements are repeated after 3 days. A mass explosion is carried out on the 5th day from the moment of loading.

 The height of the charge column after charging was 11.6-11.7 m, after 3 days - 11.3-11.4 m. The decrease in the level is due to the natural shrinkage of the charge during its crystallization. In the production of a mass explosion, charges in all wells are completely detonated.

Example 2. Carry out 5 flooded wells with a diameter of 253 mm, a depth of 20 m with a flowing water level of 3-3.5 m water-containing explosives of the type aquatol composition, wt.%: Thickened solution of ammonium nitrate - 80, TNT - 20. Wells drilled in fractured rocks. In the lower end part of 5 sleeves of laminated polypropylene 21 m long by partially pulling the sleeves with a cord, a hole with an area of 0.43 dm ³ with an equivalent diameter of 74 mm is formed and, under the influence of a load weighing 1 kg, is immersed in the corresponding wells. The sleeves are immersed for 300-320 seconds at a volumetric flow rate of water through the hole of 0.5 dm ³ / s. A charging hose is placed in the sleeves and 900 kg of a water-containing explosive of the Aquatol type are pumped through it. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.7-11.8 m, after 3 days - 11.4-11.5 m. In the production of a mass explosion, the charges detonate completely.

Example 3. Carry out charging 5 waterlogged wells with a diameter of 253 mm, a depth of 20 m with a flowing water level of 8-8.5 m water-containing explosives such as aquatol composition, wt.%: A thickened solution of ammonium nitrate - 87.7; mineral oil - 2.3; TNT - 10. Wells drilled in fractured rocks. According to Example 1, a hole with an area of 1.65 dm ² with an equivalent diameter of 145 mm is formed in the lower end part of the sleeves from a polyamide film according to Example 1 and, under the influence of a load of 1 kg, is immersed in the corresponding wells. The sleeve is immersed for 80-85 seconds with a volumetric flow rate of water through the hole 5-5.2 dm ³ / s. In each sleeve, a charging hose is placed in turn and 850 kg of water-containing explosive of the Aquatol type are pumped through it. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.4-11.5 m, after 3 days - 11-11.1 m. In the production of a mass explosion, the charges are fully detonated.

Example 4. Carry out loading 5 waterlogged wells with a diameter of 180 mm, a depth of 15 m with a flowing water level of 3-4 m with an aqueous explosive of the type aquatol composition, wt.%: Thickened solution of ammonium nitrate - 80, trotyl - 20. Wells are drilled in fractured rocks, containing sulfide impurities. According to Example 1, a hole of 1.43 dm ² with an equivalent diameter of 135 mm is formed in the lower end part of the laminated polypropylene sleeves according to Example 1 and, under the influence of a load of 1 kg, is immersed in the corresponding wells. The sleeves are immersed for 30-35 seconds with a volumetric flow rate of water through the hole 3-3.3 dm ³ / s. In each sleeve, a charging hose is placed in turn and 350 kg of water-containing explosive of the Aquatol type are pumped through it. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 8.4–8.5 m, after 3 days - 8.2–8.3 m. During the production of a mass explosion, the charges detonate completely.

Example 5. Five waterlogged wells are charged with a diameter of 253 mm, a depth of 20 m, and a flowing water level of 3-3.5 m with an aqueous explosive of the type aquatol composition, wt.%: Thickened solution of ammonium nitrate - 80, TNT - 20. Wells drilled in fractured rocks. In the lower end part of 5 sleeves of laminated polypropylene 21 m long by partially dragging the sleeve with a cord, a hole of 0.6 dm ^{2 is formed} , a piece of a 200 mm long plastic pipe with an oval cross-section with an opening area of 0.43 is alternately inserted through each hole through the hole dm ² and an equivalent diameter of 74 mm, they are pressed against its walls by the wall of the sleeve with a cord and bend the linear portion of the sleeve between its end and the lower edge of the pipe segment into the sleeve. Hoses under the influence of a cargo weighing 1 kg are immersed in the corresponding wells. The sleeves are immersed for 300-320 seconds at a volumetric flow rate of water through the hole of 0.5 dm ³ / s. A charging hose is placed in the sleeves and 900 kg of a water-containing explosive of the Aquatol type are pumped through it. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.7-11.8 m, after 3 days - 11.4-11.5 m. In the production of a mass explosion, the charges detonate completely.

 Example 6. The process is carried out according to Example 1, except that through the formed hole inside each sleeve, a spacer ring with an inner diameter of 160 mm and a weight of 1 kg is alternately introduced and a linear portion of the sleeve is bent between its end and the ring inside the sleeve. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.6-11.7 m, after 3 days - 11.3-11.4 m. In the production of a mass explosion, the charges detonate completely.

Example 7. The process is carried out according to Example 2, except that before placing the charging hose, each sleeve through its upper part is additionally filled with water in an amount of 400 dm ³ . Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.7-11.8 m, after 3 days - 11.5-11.6 m. In the production of a mass explosion, the charges detonate completely.

Example 8. The process is carried out according to Example 2, except that simultaneously with the placement of the charging hose, each sleeve through its upper part is additionally filled with water in an amount of 400 dm ³ . Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.7-11.8 m, after 3 days - 11.5-11.6 m. In the production of a mass explosion, the charges detonate completely.

 In Examples 9-11, the process is conducted using prohibitive parameter values.

Example 9. The process is carried out according to Example 1, except that they form a hole with an area of 4 dm ² with an equivalent diameter of 225 mm. Hose immersion is carried out only in 2 wells; immersion in 3 wells is stopped due to abutment of the lower end part of the arms in the unevenness of the walls of the wells. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11.4 and 11.6 m, after 3 days - 6.5 and 4.8 m, respectively. The decrease in the height of the charge in the wells is explained by mechanical damage to the walls of the sleeves due to friction against the walls of the wells and sharp edges of cracks and, as a result, charge spreading over cracks. Wells recharge with regular explosives and produce a massive explosion.

Example 10. The process is carried out according to Example 2, except that they form a hole with an area of 0.36 dm ² with an equivalent diameter of 68 mm. The sleeve is immersed in the first well for 1200 seconds at a volumetric flow rate of water through the hole of 0.42 dm ³ / s. Hoses are not immersed in subsequent wells due to unacceptably low process productivity.

 Example 11. The process is conducted according to Example 10, except that the immersion of the sleeves is carried out under the action of a reinforced load weighing 2.5 kg. The placement of the charging hose is carried out inside only three sleeves; it is not possible to place a charging hose inside two sleeves due to squeezing the walls of the sleeve with water. Measurements are carried out according to Example 1.

 The height of the charge column after charging was 11, 10.6 and 11.2 m, after 3 days - 2.5, 6.5 and 4.8 m, respectively. The decrease in the height of the charge in the wells is explained by mechanical damage to the walls of the sleeve when the charger is placed inside it hose and, as a result, the spreading of the charge along the cracks and washing it out with running water.

 As can be seen from the above examples, the proposed method can improve the reliability of the protection of the charge from leaching and from spreading along cracks in the walls of the wells, as well as to increase the productivity of the process of loading the wells with a water-containing explosive. Filling the sleeve with water in the well contributes to the unhindered placement of the charging hose inside the sleeve, eliminating mechanical damage to its shell. The complete isolation of the charge of a water-containing explosive from the bottom and walls of the well increases the safety of work during the explosive breaking of ores and rocks containing sulfide impurities.

Claims (3)

1. A method of loading flooded wells with a water-containing explosive, comprising immersing a sleeve made of a waterproof material in the well, placing a charging hose inside the sleeve and mechanically feeding a water-containing explosive through it, characterized in that it is formed before the sleeve is immersed in the well in its lower end part a hole through which, when immersed in the well, the sleeve is filled with water located in the well, while the area of the hole is chosen such that the volumetric flow rate rows therethrough was not less than 0.5 ^dm3 / s, and the maximum equivalent diameter of the holes does not exceed 0.85 borehole diameter.  2. The method according to claim 1, characterized in that a spacer element is introduced through the hole into the sleeve, and the linear portion of the sleeve between its end and the lower edge of the spacer element is bent into the sleeve.  3. The method according to claim 1 or 2, characterized in that before or simultaneously with the placement in the sleeve of the charging hose, the sleeve is additionally filled with water through its upper part.