RU2232372C1 - Device for charging of holes with running water on open pits by nonwater proof explosives and method for its use - Google Patents

Abstract

FIELD: mining industry, in particular, blasting operations on open pits.

SUBSTANCE: the device for charging has three main assemblies: a head consisting of a section of pipe and a cover installed on which branch pipes for supply and exhaust of compressed air firmly fixed in the mouth of the hole. The device for fastening of the head represents a rubber apron firmly attached to the lower part of the head pipe section. The apron is reinforced by flexible strong longitudinal elements with a low extensibility. The lower part of the apron is cut into longitudinal strips with a length equal to several diameters of the hole. The second assembly is a hose having a diameter exceeding the diameter of the whole, it is made of flexible material resistant to water and explosives. The hose lower end is sealed and provided with a load for dipping in water. The hose is passed through the head pipe section to the hole bottom. And its upper end is straightened on the upper section of the pipe and, enveloping the top of the pipe, is hermetically clamped on it through gaskets by the head cover by means of clamps. The third assembly are drain hoses of water-resistant material with a sufficient transverse rigidity, passing along the hole walls from the bench surface to the hole bottom. The hose gets straightened at a smooth supply of compressed air through the branch pipe. The lower longitudinal strips of the apron are pressed by air to the hole walls providing for unfastening of the head in the hole mouth, and water is pressed out of the hole through the hoses. After removal of water the air pressure in the hose is released, the hoses are extracted, the cover is opened, and the hose is filled with explosive and primers are installed, and the upper part of the hole is filled up with stemming. Then, the head is extracted. Thus, the process of hole charging is over.

EFFECT: enhanced reliability and efficiency of operations in charging of flooded holes, holes with running water inclusive.

6 cl, 2 dwg

Description

The invention relates to mining, and more specifically to open blasting in quarries using borehole charges.

The loading of wells with running water in open pits, and about 70% of such wells in Russia, by non-water-resistant explosives is one of the urgent problems. The urgency of the problem arose from the beginning of widespread use in quarries of ammonium nitrate explosives for blasting with borehole charges, since these explosives, having a number of advantages, do not have the necessary water resistance. The solution to the problem went in two directions: in the direction of giving the ammonium nitrate explosives sufficient water resistance and in the direction of developing devices to charge flooded wells with non-water resistant explosives.

Of the many inventive proposals of devices, none of them has not been widely used due to their inherent disadvantages.

As a prototype of the invention, the device is taken, according to the copyright certificate of the USSR No. 1693316, class. E 21 C 37/30, 1992, intended for drainage of wells. The essential features of the prototype that are consistent with the invention are: the presence of drainage devices in the prototype device, which are called hoses or hoses in the description from the wellhead to its bottom, the presence of a sleeve inflated with compressed air, and the presence of a head with a cap on which the nozzle is located for supplying compressed air having a device for fastening the head in the upper part of the well, having a support element that limits the depth of immersion of the head in the well, and to the structural element the head is hermetically attached to the top of the sleeve.

The essential features of the prototype, but not coinciding with our invention, are: a mechanism for fastening the head in the borehole in the form of a spacer cone, which when moving upward by the action of a screw drive, pushes the metal petals of the casing of the head all the way into the borehole walls, the presence of a mesh cylinder which fixed the lower end of the sleeve, as well as the material of the sleeve, which is characterized as elastic.

The main disadvantages of the prototype are the following:

1. Reliable fastening of the head at the wellhead is not ensured. The fact is that the shape of the cross section of the well deviates significantly from the circle: it has protrusions and depressions on the walls. The ends of the petals under the action of a bursting cone move all the time being on the correct circles. Therefore, of all the petals, as a rule, only the first three will approach the protrusions on the walls and abut against them, taking on the entire load, moreover, the remaining ones will remain inactive. Consider an example of a well with a diameter of 250 mm and a depth of 20 m. The optimal pressure of compressed air for it will be about 4 kg / cm ² , therefore, the force pushing the head out of the well will reach 2000 kg. It should be balanced by the friction forces of the petals on the borehole walls. For reliability, we take a margin of 50%, i.e. together rely on the friction force on one petal of the order of 1000 kg. Even if we take the coefficient of friction equal to 0.3, then the pressure force of the petal on the rock will reach 3000 kg. Since the contact area between the petal and the rock, judging by the description and drawing, does not exceed 1 cm ² , the pressure on the rock will be approximately 3000 kg / cm ² , which is 3 times higher than the destructive pressure for granite and 6 times for limestone and sandstone. Therefore, the collapse of the protrusion will occur and the petals will not rely on a monolithic rock, which will not ensure the reliability of fixing the head in the well. The reliability of the mechanism would be improved if at the end of the petal to provide a part that increases the area of contact with the rock.

2. The lack of tightness of the lower end of the sleeve does not provide reliable protection of the charge of a non-water-resistant explosive against the effect of water on it in wells with significant flow, given that in practice the charge dwell time from the moment of loading to blasting reaches 7 or more days.

3. In the section of the sleeve adjacent to the place of its attachment to the body of the bursting cone, a breakthrough of the wall of the sleeve by the pressure of compressed air is possible, since only atmospheric pressure counteracts it in this section.

Our invention aims to eliminate the disadvantages of the prototype and solve two problems of the practice of blasting in quarries:

1. Using the proposed device to charge wells with running water in quarries of medium and low power with non-water-resistant explosives, including cheap ones manufactured at the places of their consumption, explosives of the type “ammonium nitrate-diesel fuel” (ASDT), using simple techniques and inexpensive materials, while reliably protecting the charge from the effects of water for a long time that goes beyond the requirements of the practice of blasting in quarries.

2. The proposed device can be used in powerful quarries for loading flooded wells with water-containing ammonium nitrate explosives sensitized with TNT and emulsion explosives, simplify the loading technology and instead of pumping explosives under a water column, charge the wells by filling them from the surface of the ledge. In this case, the prospect arises of the possibility of changing the composition of explosives in the direction of reducing its cost without loss of quality.

To accomplish the tasks, the device is composed of the following main structural units, the interaction of which ensures the achievement of a given effect.

The first main unit is the head installed at the wellhead and firmly fixed in it. The head consists of a segment of pipe with a diameter smaller than the diameter of the well, and a length equal to several diameters, and a cap with a nozzle for supplying compressed air. The embodiment provides for the installation of an additional nozzle with a large bore for the release of compressed air. On the pipe segment there are supporting elements that limit the depth of immersion of the head in the well. A rubber apron is attached to the lower part of the pipe section, reinforced with flexible longitudinal elements with low extensibility, and the lower part of the apron is cut into longitudinal strips.

The second main unit is a sleeve with a diameter larger than the diameter of the well, the lower end of which is sealed and supplied with cargo. The sleeve is passed through a pipe segment to the bottom of the well, and its upper end is straightened on the upper section of the pipe segment and, covering it, is clamped through the gaskets by the head cover by means of clamps.

The third main unit is the drainage hoses, passed along the walls of the wells to the bottom. The upper ends of the hoses are located on the surface in places designed to receive the water to be drained. In an embodiment, the lower ends of the drainage hoses are provided with check valves.

The device operates in two stages. In the first stage, compressed air is supplied to the sleeve through the nozzle from the compressor, under the influence of which the sleeve straightens, pressing against the wall of the pipe segment, then the apron, pressing its longitudinal strips to the walls of the well, and finally to the surface of the water column, exerting pressure on it, under the influence of which water through hoses is removed from the well to the surface. At the same time, the end part of the sleeve adjacent to the water column unfolds until the removal of water from the well is completed. At the same time, sources of running water are locked. Thus, in the first stage, the device operates as a means of removing water from the well. In the second stage, after the compressed air is released from the sleeve and the drainage flanks are removed from the well, the head cover is opened, and through the funnel inserted into the pipe section, the BB sleeve is filled with the gunmen installed, and the remaining part of the well is filled with clogging. After removing the head from the well and up to the moment of the explosion, the sleeve works as a means of protecting the explosive from water.

The essential features that distinguish the head of our device from the head of the prototype are the presence of a pipe section in our head, to the lower part of which a rubber apron is attached, reinforced with flexible, strong longitudinal elements with low extensibility, and the bottom of the apron is cut into longitudinal strips. An apron has two functions.

The apron strip, pressed through the wall of the sleeve with compressed air pressure close to the uneven walls of the well, serve as a device that secures the head at the wellhead. Moreover, the greater the pressure of compressed air in the sleeve, the proportionally greater is the fixing force. The second function of the apron is that part of it, adjacent to the pipe segment, serves as a support for the sleeve, preventing its destruction by the pressure of compressed air.

The essential features that distinguish the sleeve in our device from the sleeve in the prototype are the tightness of the lower end of the sleeve, equipped with cargo, and other tight connection of the upper part of the sleeve to the head of the device. The material of our sleeve is required to be resistant to water and explosives. The prototype sleeve is made of plastic material, and ours is made of flexible material that allows forming folds on the walls of the sleeve with a 180 ° bend without violating the integrity of the material. An example of real materials satisfying this requirement is polyethylene and polypropylene - widespread and fairly cheap materials.

The essential features of our drainage hoses from the corresponding prototype devices are the manufacture of them from a waterproof material and the requirement that they have a transverse stiffness that provides an insignificant decrease in their cross-section when exposed to the outer surface of the hoses with a pressure of several kg / cm ² , since they have such compressed air pressure are subjected during operation and so that they have a longitudinal flexibility sufficient to allow them to be wound on a drum and a smooth outer surface Not to damage the wall of the sleeve when removing the tubing from the well. An example of such a product is a reinforced rubber hose.

The technical result of using the invention is the provision of solutions to the problems posed at the beginning of the section on the essence of the invention.

Figure 1 shows the proposed device installed in the well at the stage of removal of water from it.

Figure 2 presents a cross-sectional view of the device along AA.

The following is a description of the device.

The device consists of three main nodes. The first node is the head installed at the wellhead and firmly fixed in it. The head consists of a segment of pipe 1 with a diameter smaller than the diameter of the well, and a length equal to several diameters, and a cover 2 with a pipe 3 for supplying compressed air. Figure 1 shows an embodiment of the cap with an additional nozzle 4 with an enlarged bore for quick release of compressed air. Supporting elements 5 are attached to the pipe segment, limiting the immersion depth of the head into the well. A rubber apron 6 is attached to the lower part of the pipe segment 1, reinforced with flexible strong longitudinal elements with low extensibility, and the lower part of the apron is cut into longitudinal strips 7, which, pressed by the pressure of compressed air through the walls of the sleeve 9 to the walls of the well, perform the function of a mechanism that unfastens the head in the well, and the part of the apron 8, adjacent to the lower cut of the pipe segment of the head, serves as a support for the sleeve, preventing its destruction by the pressure of compressed air.

The second main unit is a sleeve 9 with a diameter larger than the diameter of the well, the lower end of which is sealed and provided with a load 10 for immersing the lower end to the bottom, and the upper end of it 11 is straightened on the upper section of the pipe segment and, covering it, is clamped through the sealing gaskets by the cover 2 by clamps. The material of the sleeve is resistant to water and explosives and has the flexibility to form folds on the walls of the sleeve with a bend of 180 ° without destroying the integrity of the material. Examples of materials that meet these requirements are common in the technique of polyethylene and polypropylene.

The third main unit is the drainage hoses 12, passed along the walls of the borehole to the bottom, and their upper ends are brought to the outer surface at the opening of the water extracted from the borehole. The hoses have a smooth outer surface, are made of waterproof material, have a transverse stiffness, providing an insignificant decrease in their cross-section when exposed to external pressure of several kg / cm ² , and a longitudinal flexibility sufficient to be able to wind them on drums. In an embodiment, the hoses are provided with check valves at their lower ends.

An example of a product that meets these requirements is a rubber reinforced hose, variants of which are widely used in practice.

The method of loading wells with running water in quarries using the described device is to perform the following sequential actions. At the beginning, a segment of the pipe 1 of the device head is lowered into the upper part of the waterlogged well until its supporting elements 5 come into contact with the step surface, then, at predetermined places of the head, water drainage hoses 12 are lowered into the well between the pipe end and the bottom. After that, the necessary weight is laid in the opened lower end of the sleeve to ensure immersion of the sleeve in water.

Dense pieces and drafts of explosives can be used as cargo. Then the lower part of the sleeve is sealed by tying it with twine or thin twine and lower the sleeve through the length of the pipe to the very bottom of the well 10. The excess upper part of the sleeve is cut to the required length, unfold it on the upper cut 11 of the pipe length and, covering it, clamp it tightly through sealing gaskets with cover for 2 heads by means of clamps. After connecting to the pipe 3 on the cover 2 of the hose from the compressor, compressed air smoothly falls into the sleeve, providing pressure to effectively remove water from the well. In an embodiment, drainage hoses are used, at the lower ends of which check valves are installed to avoid backflow of water when removing the hoses from the well. After the expiration of water, the air pressure in the sleeve is quickly released. In a variant of the method, a device is used with an additional pipe 4 of increased passage section on the head cover 2.

After depressurization, the cap 2 of the head is opened and at the same time begin to remove the drainage hoses from the well and begin to fill the sleeve BB. To quickly fill the sleeve into the hole in the pipe segment 1, a loading funnel is inserted. When filling the sleeves of the explosives set the militants. The rest of the well is filled with stemming. Then the head is removed from the well. This completes the loading of the well and it becomes prepared for subsequent technological operations for blasting.

Claims (6)

1. Device for charging wells with running water with a non-water-resistant explosive, containing drainage hoses located along the wall of the well to its bottom, a sleeve whose diameter exceeds the diameter of the well, passing from the bottom of the well to the top to supply compressed air to it, a head consisting of a section of pipe with a diameter smaller than the diameter of the well, with the upper part of the sleeve fixed on it, with a cover on which a pipe for supplying compressed air is located, and having a device for fixing it at the wellhead and an element limiting the depth of immersion of the head into the well, characterized in that the drainage hoses are made of water-resistant material, have a smooth outer surface, lateral stiffness, providing an insignificant decrease in their flow cross section under the influence of external pressure and a longitudinal flexibility sufficient to wind them onto the drums and the sleeve is made of a material resistant to water and explosives, which has the flexibility to form folds with a bend of 180 ° without damaging the walls of the sleeve integrity of the material at a pressure of compressed air, the lower end of the sleeve being sealed and provided with a load to ensure its immersion through water to the bottom of the well, while part of the sleeve is passed through the head, the upper end of which, when straightened, covers the upper section of the head pipe section and is hermetically clamped through sealing gaskets by the head cover by means of clamps, and the device for securing the head at the wellhead is made in the form of a rubber apron reinforced with flexible, durable longitudinal elements and, while the upper part of the rubber apron is firmly fixed on the lower part of the pipe section of the head, the lower part of the rubber apron is cut into longitudinal strips, which, when compressed air is fed into the sleeve, can be pressed against the borehole wall, and the middle part of the apron adjacent to the lower cut piece of pipe head, serves as a support for the sleeve when applying pressure to it of compressed air. 2. The device according to claim 1, characterized in that an additional nozzle is installed on the head cover for releasing compressed air from the sleeve, having a larger cross-section than that of the nozzle for pumping air. 3. The device according to claim 1 or 2, characterized in that check valves are installed in the lower ends of the drainage hoses. 4. A method of loading wells with running water in quarries, according to which a sleeve is lowered into the flooded well connected to the head of the device, which is fixed at the wellhead until its supporting elements come into contact with the step surface, in the specified places of the head, the gap between the head and the wall of the well is lowered the drainage hoses to the well to the bottom, a hose from the compressor is connected to the nozzle on the head cover and compressed air is supplied to the sleeve, through which the sleeve displaces water from the well through discharge hoses to the surface at the places of its discharge, the head and drainage hoses are removed from the well, the explosive sleeves are filled with the fighters installed, and after loading the well, the stemming is filled in, characterized in that the device head is first lowered into the mouth of the flooded well after being immersed in the drainage hose bore into the open end of the sleeve, load is laid, the end of the sleeve is sealed and the sleeve is lowered through the head with the cover open to the bottom, the upper end of the sleeve is straightened to the upper cutting a piece of the head pipe and, covering it with the upper part of the head pipe, clamp it tightly through the gaskets with the head cover by means of clamps, gently pressurized air into the sleeve, through which the head is fixed in the well, and after the water is displaced from the well, air they are quickly released from the sleeve, the head cover is opened and a loading funnel is inserted into it, at the same time, the BB sleeve is filled and the drainage hoses are removed from the well, lowered into the well militants, and the head of the device is removed from the wellhead after loading the well. 5. The method according to claim 4, characterized in that an additional nozzle for quick release of compressed air is placed in the cap of the head. 6. The method according to claim 4, characterized in that the lower ends of the drainage hoses are equipped with check valves.

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