RU2563266C1 - Method of formation of short combined stemming of blast holes and device for its implementation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method of formation of short combined stemming includes the formation of the lower fill part from inert fine materials with the height of 1.5-2 diameters above air interval and formation on the lower fill part of the top part from stone material elements to the height of 0.5-1.5 well diameters. On the lower part the transport container installed in the soft bag with stone material elements of 0.2-0.6 of well diameter is lowered, it is unloaded and removed from the well. After that again the inert fine material is filled to the height 1-1.5 of well diameter on which again the stone material is unloaded from the transport container. The process is repeated until full formation of the combined stemming with the height no more than 10 well diameters. In the method the transport container is used which is made in the form of metal or plastic cylinder. The top ring of the container with the size 0.8-0.9 well diameter, where the bars are evenly fixed with the step excluding loss of small pieces of stone material, is fitted with the bearing cord. The transport container is inserted into the soft bag 20-30% larger then the well diameter, fitted with ears for fastening of the bearing cord.

EFFECT: improvement of efficiency of locking of detonation products in a charging cavity by the short combined stemming and decrease of costs for its formation.

2 cl, 4 dwg

Description

The invention relates to the field of drilling and blasting and can be used in various industries using explosive cultivation of rock massifs of rocks.

It is known that the best crushing of rocks by explosion is ensured by the use of shortened stemming with an air gap above the charge / 1 /. Shortened shutdowns increase the zone of controlled crushing, reduce the oversize yield, but should have increased resistance to ejection by the pressure of the explosion gases - lock them up to the moment of destruction of the rock mass near the wellhead, therefore they are performed combined by placing various jamming elements in combination with the filling part / 2 /.

It is known the formation of a combined backfill wells as follows. First, an air gap is made over the explosive charge in a known manner, then a filling section is formed by placing loose inert material to a predetermined height. After this, a buffer gap is formed from polystyrene foam similarly to the air gap, and a cone, for example concrete, is lowered upwards on it with a cord. The space between the walls of the borehole and the cone to its entire height is filled with crushed stone, and then finely dispersed inert material, for example drill cuttings, is poured to the wellhead.

However, as laboratory tests and experimental explosions have shown, when a cone is placed in a well, it is installed arbitrarily relative to the vertical and the gravel is placed unevenly from different sides of the cone, which reduces the reliability of locking the explosion products. In addition, there is a risk of damage to the conductor of the initiating pulse when backfill gravel to a great depth.

It is also known a device for locking the explosion products in the charging cavity of the well in the form of a combined backfill blasting hole with elements of stone material, including the bottom backfill of inert bulk materials above the air gap and the upper combined part, in which the upper combined part of the stemming is divided into two segments: lower section up to three well diameters, filled with elements of stone material with a size of 0.2-0.6 well diameters, interspersed with an inert loose mat Rial size less than 5 mm, and an upper filled to the top of the well with the same inert particulate material / 4 /.

Blocks of this design either do not crash at all, or they are ejected 120-160 ms after the departure of ordinary filling muds of the same length; This ensures a long duration of locking the detonation products in the charging cavity. However, when forming such blockages, the stones have to be dropped one at a time and with large diameters of the wells at a length of 10 diameters (2.5 m for 250 mm wells), the stones acquire a high speed and can damage the conductor of the initiating impulse.

The technical problem to which the proposed invention is directed is to increase the efficiency of locking detonation products in the charging cavity with a short combined stemming and reducing the cost of its formation.

The problem is achieved in that in the method of forming a short combined stemming of blast holes, including the formation of the lower filling part from inert finely dispersed materials above the air gap and the upper combined part from embedded elements, according to the invention, a lower filling part with a height of 1.5-2 bore diameters is formed a layer of stone material elements to a height of 0.5-1.5 borehole diameter, for which a transport container from the element, which is installed in a soft bag, is lowered to the lower part stone material with a size of 0.2-0.6 borehole diameter, unload it and remove it from the borehole, after which inert finely dispersed material is again poured to a height of 1-1.5 borehole diameter, onto which stone material is again unloaded from the transport container; the process is repeated until complete formation of the combined stemming with a height of not more than 10 well diameters.

The task is also achieved by the fact that a short combined stemming of blast holes is formed by a transport container, according to the invention, made of metal or plastics, including a top ring provided with a support cord with a size of 0.8-0.9 diameter of the well, in which the rods are uniformly fixed with a pitch, excluding the loss of small pieces of stone material; the transport container is inserted into a soft bag with a size of 20-30% larger than the diameter of the well, equipped with ears for attaching the carrier cord.

The drawings schematically show the process of forming a short combined stemming of blast holes using a transport container.

In FIG. 1 schematically depicts the process of lowering into a well a transport container with stone material; in FIG. 2 - the position of the soft bag with stone material after removal of the transport container; in FIG. 3 - formed a short combined stemming of blast holes. In FIG. 4 shows a transport container loaded with stone material.

The method of forming a short combined stemming of blast holes up to 10 well diameters is as follows. After charging, transport containers 2 are brought to each blast hole 1, filled with elements of stone material 3, including large stones 4 of 0.5-0.6 diameter of the well mixed with medium stones 5 of size 0.2-0.4 of the diameter of the well. Their number is determined by the height and number of layers of stone material planned for placement in this well.

The transport container 2 is made of metal or plastic material and is an upper ring 7 provided with a support cord 6 of size 0.8-0.9 of the diameter of the well 1, on which the rods 8 are evenly fixed with a step that excludes the loss of small pieces of stone material. The height of the rods 8 is selected so that the volume of the transport container accommodates stone material, allowing it to be placed in a layer with a height of 0.5-1.5 diameter boreholes. The purpose of the transport container 2 is to form elements of stone material into a pole with a diameter smaller than the bore diameter of the well 1. The transport container 2 is inserted into a soft bag 9 made, for example, of polypropylene, 30-50% larger in diameter of the well 1 and equipped with ears 10 to pass the carrier cord 11. A soft bag 9 serves to prevent the spillage of stone material elements from the transport container 2 when carrying it and lowering it into the well 1, therefore, its height may be minimal. In addition, due to the considerable width, the soft bag 9 allows the stone material exiting the column from the transport container 2 to occupy the entire section of the well due to its creep.

In the well 1 above the charge of BB 12 in a known manner, an air gap 13 is formed, the height of which is equal to the difference between the depth of the well 1 and the total height of the charge of BB 12 and the stemming. Above the air gap 13, the lower filling part 14 is formed with loose inert material 15, for example, drill cuttings, filling it to a height of 1-2 well diameters. After that, the formation of the first layer 16 of the elements of the stone material of the upper combined part of the stemming unit is started. For this, the carrier cord 6 from the upper ring 7 is fixed on the surface of the block, for example, to the stone and using the double carrier cord 11 passed through the ears 10 of the soft bag 9, the transport container 2 is brought up and lowered into the well 1. After touching the soft bag 9, the filling part 14, the carrying cord 11 is alternately pulled from the ears 10 at one end and the transport container 2 is removed from the soft bag 9 by the carrying cord 8, shaking it to better precipitate the elements of the stone material, and then removing it from the well. It is the execution of the wall of the transport container 2 of the rods that ensures its minimum contact with the elements of the stone material and, accordingly, their minimum clamp. When the transport container is made in the form of a continuous pipe, the stone material wedges in it and does not fall out even with repeated strong shaking. And the vibration of the rods 8 with shaking release a few clamped pieces and there is a complete release of the transport container 2 from the stones.

The soft bag that has been removed 9, under the action of the mass of stone material, is straightened and pressed against the walls of the well 1, copying its irregularities and remaining, as the experimental charging showed, open. At the same time, due to smooth spreading, the soft bag 9 presses the conductor of the initiating pulse 17 against the walls of the well 1, thereby eliminating the possibility of its damage when forming a layer of stone material 16 of the combined part of the stemming unit.

After the formation of the layer of stone material 16 into the well 1, the bulk inert material 15 is again poured in portions until the height of the layer of backfill 18 is reached above the layer of stone material 16 in 1-1.5 diameter of the well. Part of the bulk inert material 15 enters the soft bag 9, filling the gaps between the elements of the stone material, which helps to increase the gas tightness of the stemming. Then, the process of forming layers of stone material and filling is repeated until the well section 1 allocated for the bottom hole is completely filled.

After detonation of the explosive charge 12 in the charging cavity, the pressure of the detonation products sharply rises to several tens of thousands of atmospheres and there is an impact of gases on the lower part 14 of the bottomhole, substantially mitigated by the air gap.

It was experimentally established / 4 / that in the backfill of granular materials at the first time after the detonation of the charge, the bottom-hole material is compacted in the form of a plug and tightly wedged in the well. After compaction, regardless of the material used, the stem is ejected with increasing speed, the charging cavity is depressurized and some of the detonation products are ejected from it without having done useful work. To eliminate this phenomenon, in the combined part of the stemming, an alternation of layers 16 with elements of stone material and filling layers 18 is provided.

Starting movement, the lower filling part 14 of the stemming unit acts on stones 4 and 5, wedging them together and into the walls of the well 1. In this case, large stones 4 can collapse to stones of medium size 5, which, in turn, turn into smaller crushed stone. The process is spasmodic in nature and arises and develops in each layer 16 anew, which as a whole significantly increases the time required to discharge the clog.

During experimental explosions in wells with a diameter of 250 mm, layer-by-layer placement of stone material elements in the combined stemming was carried out by a transport container with a diameter of the upper ring of 200 mm with a bar length of 400 mm (see Fig. 4), and the drill cuttings were covered with a normal shovel. The outflow from a combined stemming hole 1.5 m high (6 well diameters) began 240 ms after the start of the blast, while the discharge of backfill heights 2.5 m and 3.5 m (10 and 14 well diameters, respectively) began simultaneously after 160 ms. Combined stemming with a height of 2 m (8 well diameters) was not thrown out at all.

The use of a transport container for the formation of combined jamming of blast holes as compared with the prototype eliminates damage to the conductor of the initiating impulse placed by the clogging stones, increases the reliability of the clogging regardless of the state of the walls of the wells. Indeed, it was on a section from the surface of a ledge with a height of 10-15 diameters that the borehole of the overlying ledge was located, which is why there is the greatest disturbance of the walls of the well and the outfalls in them. And the spread of a soft bag with a known large size than the nominal diameter of the well allows you to copy the walls of the well and fill in all the bumps in them and outfalls with stone material, thereby increasing its pinching and resistance to ejection. Providing long-term isolation of the charging cavity, the stemming contributes to a more complete course of secondary reactions in detonation products and, accordingly, increases the explosion energy; this is especially important for modern emulsion explosives and coarse explosives such as granulites and grammonites, in which a significant proportion of the energy is released during secondary reactions.

Thus, the inventive method of forming a short combined stemming of blast holes and a device for its implementation in the form of a transport container allows you to form a short combined stemming precisely in the upper, most destroyed part of the well and lock the explosion products in the charging cavity until the array is destroyed. Due to this, not only the efficiency of using the energy of the explosion for crushing rocks is increased, but also the cost of using the bottomhole is reduced, since it takes up a lower height, providing an increased zone of controlled action of the explosion with all the positive consequences, as well as lower costs for the formation of the bottom hole, which allows solve the technical problem.

Sources of information taken into account

1. The effect of stemming on the degree of crushing of rocks by an explosion / G.P. Demidyuk, V.D. Rossi, N.F. Andrianov, V.A. Usachev // Sat. Blasting business No. 53/10. M .: Nedra, 1963 .-- S. 96-105.

2. Yakovenko A.I. Calculation of borehole charges in quarries // Sat. Blasting business No. 51/8. M .: Nedra, 1963 .-- S. 108-120.

3. Patent of the Russian Federation No. 2462688, IPC F42D 1/08. 2012 (prototype).

4. Patent of the Russian Federation No. 2526950, IPC F42D 1/08. 2014 (prototype).

Claims (2)

1. The method of forming a short combined stemming of blast holes, including the formation of the lower filling part of inert fine materials above the air gap and the upper combined part of embedded elements, characterized in that a layer of elements is formed on the lower filling part with a height of 1.5-2 diameter of the well of stone material to a height of 0.5-1.5 diameter of the well, for which a transport container with elements of stone material of 0.2-0.6 dia. well of the well, unload it and remove it from the well, after which the inert finely dispersed material is again filled up to a height of 1-1.5 well diameters, onto which the stone material is again unloaded from the transport container; the process is repeated until complete formation of the combined stemming with a height of not more than 10 well diameters. 2. A transport container for forming a short combined stemming of blast holes, characterized in that it is made of metal or plastics, includes an upper ring 0.8-0.9 with the diameter of the well provided with a bearing cord, in which the rods are uniformly fixed with a step that eliminates loss small pieces of stone material; the transport container is inserted into a soft bag with a size of 20-30% larger than the diameter of the well, equipped with ears for attaching the carrier cord.

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