RU2088893C1 - Method of charging of flooded downcast wells with water-containing explosives - Google Patents

Abstract

FIELD: mining industry and construction, conducting of sparing, blasting operations in flooded rocks. SUBSTANCE: after the water-proof flexible hose is placed in the well it is fixed in the bottom-hole formation zone of the well to its walls around the edges to a height of 1 to 5 well diameters by pushing-apart forces acting from the hose interior; a mixture of components with a chemically active gas-generating addition introduced in the process of charging is used as water-containing explosive; when fed to the hose this mixture has a density exceeding the well water density, and the density of finished water-containing explosive after completion of chemical reaction of gas-generating addition at least with one of the components of the water-containing explosive is lower than the well water density. EFFECT: facilitated procedure. 2 cl

Description

 The invention relates to the field of blasting, and in particular to methods of charging downstream wells of the WWW, which is a mixture of components with a chemically active gas-generating additive (GGD) introduced into it during charging, and can be used in mining and construction in blasting operations in flooded rocks using "gentle" technology: achieving a crystal-saving effect, contour blasting, block stone breaking, etc.

It is known that HERBs are a mixture of components, usually non-explosive, which are sensitized with gas bubbles to impart explosive properties and increase detonation ability by introducing chemically active GHD, for example, sodium nitrite, which interacts with any component (ammonium nitrate) VSVV. GHD not only sensitizes VSVV, but also reduces its density to 95–30% of the density of the initial mixture of components of VSVV [1]
Thus, the density of these high explosives can be reduced to 350,400 kg / m ³ , which allows them to be used for blasting according to the "gentle" technology. However, this application is only possible when loading dry wells. Most of the wells are flooded and the use of these water-water supply devices for their loading is impossible, because the final density of explosives is significantly lower than the density of well water.

Closest to the proposed one is a method of charging flooded downhole wells of the WWW, including the placement in the well of a waterproof flexible sleeve with a muffled lower end and feeding into this sleeve of the WWW [2]
To accommodate a sleeve made of a seamless high-pressure and low-density polyethylene film 200 microns thick, 3-4 kg of a drill head are poured into the lower end of the well in the borehole, this end is sealed with a double bend with twine and lowered into the wellhead. Then the sleeve is lowered into the well until its bottom, and the upper end of the sleeve is strengthened above the wellhead by means of a receiving cylinder and a hoop. The supply of HSSE is carried out into the sleeve from the wellhead or through a charging hose lowered to the bottom of the sleeve with a simultaneous rise as the HSE sleeve is filled.

The specified method cannot be used in blasting according to the "gentle" technology in flooded rocks, because the density of the explosive water prepared for the explosion should be higher than the density of well water. For the same reason, VSEM cannot be used as explosive explosives sensitized by chemically active GHD to a density that satisfies the conditions of “gentle” blasting, i.e. significantly less than 1000 kg / m ³ .

 The purpose of the invention is the creation of a method for loading downstream wells of WWW, which can be used for blasting according to the "gentle" technology in flooded rocks; an increase in the adhesion of the charge column to the walls of the well and the possibility of using cheap, non-deficient and widely used in the industry local-type explosive explosives, which are a mixture of components with chemically active GHD introduced into it during charging.

 The goal is achieved by the fact that in the known method of loading flooded downhole wells of the WWW, including the placement in the well of a waterproof flexible sleeve with a plugged lower end and feeding into this sleeve of the WWW, according to the invention, after placement in the well, the sleeves are fixed in the bottom of the well to its walls throughout perimeter and to a height of 1.5 borehole diameters by bursting forces acting from the inner cavity of the sleeve, and as a BCB, a mixture of components with the chemical introduced into it during loading is used and the active gas generating additive (GGD), and this mixture is fed into the sleeve has a density greater than the density of the well water and the density of the finished VSVV after completion of the chemical reaction GGD, at least one of the components VSVV less than the density of the well water.

 An emulsion explosive of the poremit type is also used as the BCB, and sodium nitrite as the GHD.

 The set of features indicated in the independent claim of the invention includes essential features, each of which is necessary, and all together are sufficient to obtain a technical result.

Fixing the sleeve before supplying it to the bottom-hole part of the well to its walls along the entire perimeter and to a height of 1 5 diameters of the well by bursting forces acting from the inner cavity of the sleeve, eliminates the flow of water into the bottom of the well under the sleeve and holds the sleeve with it charge in a flooded well after the density of the water-water supply becomes less than the density of the well water. Fixing the sleeve to a height of less than 1 diameter of the well does not create the force required to hold the sleeve and it can float, and fixing to a height of more than 5 diameters of the well does not make sense, i.e., the adhesion of the sleeve in the bottom hole of the well with its walls will be known to be larger pushing force. The lower the density of the finished water in the well and the higher the height of the water column in this well, the greater should be the height of fixation of the sleeve in the bottom of the well. When using WWS with a chemically active GGD introduced during charging, the initial mixture of components of such explosives has a density of 1250 1600 kg / m ³ , which is significantly higher than the density of well water, therefore, when this mixture is fed into the sleeve, it displaces water up and through cracks in the walls of the well the surrounding array, completely filling the sleeve along the cross section of the well. During the reaction of GGD with one or several components of the high-explosive charge, the volume (height) of the charge column increases due to the formation of gas bubbles, the density of the short-wave charge decreases, becomes less than the density of water and satisfies the blasting conditions using a "gentle" technology. However, the charge does not float up, because firstly, the sleeve is retained in the well due to its preliminary fixation in the near-well part of the well, and secondly, the pressure inside the gas bubbles, commensurate with the pressure of the well water, is transmitted by the HWB and the latter uniformly presses the sleeve against the walls of the well, increasing the adhesion of the charge column with borehole walls. This eliminates the possibility of pinch sleeves with VSWB well water, violations of the continuity of the sleeve and the displacement of the charge or part of it with water. Since the mixture of components of the BCBB and the finished BCBB have a significant viscosity, for example, the viscosity of the emulsion explosives of the Poremit type is 5 • 10 ⁵ 1.2 • 10 ⁵ SPa, and the height of the charge column is tens of times or more its diameter, gas bubbles are held inside the BCB and the charge does not shrink after the completion of the GHD chemical reaction for the entire time necessary to produce the explosion.

 The use of emulsion explosives of the Poremit type as the high explosive explosive, and sodium nitrite as the GHD, can improve the performance of drilling and blasting operations, as these explosives are widely mastered in industry, promising, cheap and not deficient.

 Example 1. The flooded downhole (vertical) wells of the WWW were charged according to the “sparing” crystal-saving technology of the WWW, using emulsion explosive of the poremite type and sodium nitrite as the chemically active GHD. The emulsion matrix of poremite had the following ratio of components, wt.

Ammonium nitrate ammonium nitrate 64
Sodium Nitrate Sodium Nitrate 14
Water 15
Fuel (oil (I-40A) 5
Emulsifier (type PT) 2
Total: 100
The boreholes had a diameter of 250 mm and a depth of 18 m with a step height of 15 m. The height of the water column in the wells was 6.5 m, the specific explosive consumption was 0.5 kg / m ^{3 of} rock mass, the density of the finished explosive after completion of the GHD chemical reaction with one of the components VSVV (ammonium nitrate) 500 kg / m ³ .

 For these conditions, with a stem length (height) of 5 m, the height of the charge column should be 12.75 m, and the height of fixation of the waterproof flexible sleeve to the walls of the well with one diameter, i.e. 0.25 m. Thus, the charge mass is 306 kg, and the grid of wells is 6.4 × 6.4 m.

To achieve a given density of the finished explosive with given viscosity of the specified emulsion matrix (composition of the mixture of components) equal to 6 • 10 ⁴ SPZ, the height of the charge column, the height of the water column in the well and its diameter, the required amount of GHD is 0.32 wt. dry sodium nitrite in excess of 100 wt. mixtures of poremite components, which are introduced into this mixture in the form of a 10% aqueous solution, acidified with sulfuric acid to pH 2.

 Well loading was carried out by sequentially performing the following operations.

 A waterproof flexible sleeve with a diameter of 250 mm with a plugged lower end made of a seamless high-pressure and low-density polyethylene film 200 microns thick was placed in a non-drained well. To do this, 3 4 kg of drill head was poured into the lower end of the sleeve, this end was sealed with a double bend with twine binding and lowered into the wellhead. The sleeve was immersed in the well before its bottom, and the upper end of the sleeve was strengthened above the wellhead by means of a receiving cylinder and a hoop.

 Then the sleeve is fixed in the bottom of the well to its walls along the entire perimeter and to a height of 1 diameter of the well (0.25 m) by bursting forces acting from the inner cavity of the sleeve. To fix the sleeve, a drill rod was used, which was poured into the sleeve through the receiving cylinder. Since the density of the bayonet is significantly higher than the density of the borehole water, the lower end of the sleeve is snug against the walls of the borehole.

 After that, an intermediate detonator of T-400G checkers weighing 800 g, which was placed between the walls of the well and the sleeve, and inside the sleeve to the bottom of the well, the charging hose of the Poremit-IV charging machine was lowered into the well on two strings of a detonating cord (DS).

The supply of water-oil waves (poremite) was carried out before the bottom of the well. As the charge column formed in the direction from the bottom to the wellhead, the charge hose was gradually removed from the well. GHD was introduced into the mixture of components of explosives having a temperature of 70 ^o C during loading, when the initial density of the composition was 1340 kg / m ³ , which is significantly higher than the density of well water, which was displaced to the top of the well.

The process of interaction of sodium nitrite (GGD) with ammonium nitrate was completed 1.5 hours after the end of the supply of poremite to the well. In this case, the density of the finished poremite decreased to a predetermined value of 500 kg / m ³ .

 Then, the borehole clogging was carried out by elimination of enrichment products, an explosive network from the fire chamber was mounted and blasting was carried out.

 Example 2. The loading of wells was carried out in the same way as in example 1. However, the height of the water column in the well was 10 m. Therefore, the height of fixation of the sleeve to the walls of the well was increased and amounted to 2.5 well diameters (0.625 m). Accordingly, the stem height was reduced by 1.5 well diameters (0.375 m). Also, the dry sodium nitrite content introduced into the emulsion matrix was increased to 0.35 in excess of 100 wt.

 Example 3. The loading of wells was carried out in the same way as in example 1. However, the height of the water column in the well was 16 m. Therefore, the height of fixation of the sleeve to the walls of the well was increased to 5 well diameters (1.25 m). Accordingly, the stem height was reduced by 4 well diameters (1.0 m). Clogging by elimination of enrichment products was not performed, because above the charge was a column of water at least 2 m high. Also, the dry sodium nitrite content introduced into the emulsion matrix was increased to 0.4 in excess of 100 wt.

 When blasting borehole charges in all examples of the method, the specified quality indicators of the blasted rock mass were obtained. Shrinkage of charges did not occur during the day.

 In addition to emulsion explosives of the poremit type, the method can be implemented using other explosive explosives, for example, explosive compositions such as aquatols, HLT, etc., and sodium nitrite with thiourea, calcium or barium nitrites with sulfuric or citric acid, etc.

Claims (2)

 1. A method of loading flooded downhole wells with water-containing explosives, comprising placing a waterproof flexible sleeve with a plugged lower end in the well and supplying a water-containing explosive to this sleeve, characterized in that after placement in the well, the sleeve is fixed in the bottom of the well to its walls along its walls to their entire perimeter to a height of 1 5 borehole diameters by bursting forces acting from the inner cavity of the sleeve, and using water-containing explosives a mixture of components with a chemically active gas-generating additive introduced into it during charging, and this mixture, when fed into the sleeve, has a density higher than the density of well water and the density of the finished water-containing explosive after completion of the chemical reaction of the gas-generating additive with at least one of the components of the water-containing explosive is less than the density of well water.  2. The method according to p. 1, characterized in that the emulsion explosive type Poremit is used as a water-containing explosive, and sodium nitrite is used as a gas-generating additive.