RU2263877C1 - Method of shooting of rocks with frozen earth spots - Google Patents

Abstract

FIELD: mining; construction industry; methods of breaking rocks from massifs with lenticular permafrost massifs.

SUBSTANCE: the invention is pertaining to the field of mining and construction and is intended for breaking rocks from massifs with the lenticular permafrost spots. The technical result is improvement of the quality of crushing of rocks with the lenticular permafrost spots and a capability to control the sizes of the crushing over the whole volume of the rocks shooting. The method provides for boring of the downward primary and additionally boreholes, their charging with explosive charges (explosives), stemming of boreholes and firing of charges of explosives. At that while boring the primary boreholes in the case of presence of the lenticular permafrost spots determine their contours in plane and marks of the roofing and soil of these lenticular permafrost spots by the depth of the boreholes. The additional boreholes they drill inside the contour with a crossover of the indicated lenticular permafrost spots, but not deeper than the primary boreholes, At that determine marks of the roofing and soil of the lenticular permafrost spots by the depth of the additional boreholes, and at a charging of the additional boreholes the charges of explosives place inside the crossing lenticular permafrost spots.

EFFECT: the invention ensures improvement of the quality of crushing of rocks with the lenticular permafrost spots and a capability to control the improvement of the quality of crushing of rocks with the lenticular permafrost spots and a capability to control the sizes of the crushing over the whole volume of the rocks shooting.

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Description

The invention relates to mining and construction, and in particular to methods of blasting rocks with permafrost inclusions in open pit mining, and is intended for breaking rocks from arrays with lenticular permafrost inclusions.

A known method of blasting permafrost, including drilling downhill wells, loading them with explosive charges (HE), blocking wells and blasting explosive charges. In this case, permafrost is not crushed to its full capacity, for example, in permafrost areas, by the same blasting methods as rock formations [1], but with high specific explosive consumption [2].

However, the method does not provide a given degree of crushing during blasting of rocks with lenticular inclusions of permafrost, since there is an increased yield of oversized material from the zone of these inclusions and over-crushing of rocks containing these inclusions.

The closest technical solution to the claimed one is a method of blasting rocks with permafrost inclusions in open pit mining, including drilling downstream primary and secondary wells, loading them with explosive charges, blocking wells and exploding explosive charges [3]. Additional wells are located between the main wells, and their depth is taken equal to the length of the stemming in the main.

The specified method is effective for blasting rocks with a top seasonal frozen layer, but does not provide high-quality crushing of rocks with lenticular inclusions of permafrost, since these inclusions have different positions and power inside the destroyed massif.

The objective of the invention is to increase the efficiency of blasting rocks with lenticular inclusions of permafrost.

The technical result achieved in this case is to improve the quality of crushing of rocks with lenticular inclusions of permafrost and the possibility of regulating the degree of crushing throughout the exploded volume of rocks.

The specified technical result is achieved by the fact that in the known method of blasting rocks with permafrost inclusions in open pit mining, including drilling downstream primary and secondary wells, loading them with explosive charges, plugging wells and blasting explosive charges according to the invention during drilling the main wells in the presence of lenticular inclusions of permafrost determine their contour in plan and the marks of the roof and soil of these inclusions along the depth of the wells, additional wells are drilled inside the con round with the intersection of the indicated inclusions, but not deeper than the main wells, while the marks of the roof and soil of the inclusions are determined by the depth of the additional wells, and when charging additional wells, explosive charges are placed inside intersected lenticular permafrost inclusions.

In addition, all major wells are charged with explosive charges corresponding to the properties of rocks containing lenticular permafrost inclusions.

Also, the main wells crossing the lenticular inclusions of permafrost are charged with combined explosive charges, and explosives with a higher concentration of explosive energy are placed inside these inclusions than the explosives outside the inclusions, and the remaining main wells are charged with explosive charges corresponding to rock properties containing the lens-shaped permafrost inclusions.

Instead of combined explosive charges, it is possible to charge the main wells crossing the lenticular inclusions of permafrost with explosive charges with a higher concentration of explosion energy than explosives in the charges of other main wells.

In this case, before charging additional wells, their bottom part is clogged to a height of 2 to 5 diameters of wells above the soil of lenticular inclusions, and these wells are charged with explosive charges, the height of which is 2-5 diameters of wells below the roof of lenticular inclusions.

It is possible to clog the bottom of additional wells with water, and charge them with explosive charges after freezing this water. It is also possible to clog the bottom of these wells with a solid, solid blockage material followed by pouring water into them, the volume of which does not exceed the volume of the inter-granular space of the specified blocking material in the well.

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

The determination of the main wells in the process of drilling in the presence of lenticular inclusions of permafrost of their contour in plan and the marks of the roof and soil of these inclusions by the depth of the wells makes it possible to establish the occurrence parameters of these inclusions within the destructible massif, including their thickness along the depth of specific wells, and also to correct the design and parameters of explosive charges in the main wells to control the degree of crushing throughout the exploded volume of rocks. The location of additional wells inside the contour in terms of lenticular inclusions of permafrost ensures that each additional well intersects these inclusions over their entire area within the blasting block. Drilling additional wells with the intersection of the indicated inclusions, but not deeper than the main wells, provides a determination of the position and power of the inclusions along the depth of each additional well to the entire height of the rock volume to be destroyed. The above signs make it possible to charge additional wells with explosive charges, which are evenly placed inside the lens-shaped permafrost inclusions intersected by these wells over their entire area and volume. This increases the energy saturation of the array inside the lenticular inclusions and increases the efficiency of their crushing. In view of the foregoing, the combination of all the characteristics indicated in an independent claim claims, it is possible to improve the quality of crushing of rocks with lenticular inclusions of permafrost and makes it possible to control the degree of crushing throughout the exploded volume of rocks, which solves the problem of the invention and ensures the achievement of a technical result.

Charging all major wells with explosive charges corresponding to rock properties containing lenticular permafrost inclusions simplifies the technology of loading and jamming wells, as well as the installation of an explosive network.

Charging the main wells crossing the lenticular permafrost inclusions with combined explosive charges, in which explosives with a higher concentration of explosion energy are placed inside these inclusions than explosives outside the inclusions, and charging the remaining main wells with explosive charges corresponding to the rock properties containing the indicated inclusions allows increase the energy saturation of the array inside the inclusions, increase the efficiency of their crushing, and it is advisable with a very significant difference in the explosivity of the host rocks and li ne, especially air at positive temperatures, e.g., during the summer period.

Charging the main wells intersecting lenticular inclusions of permafrost with explosive charges with a higher concentration of explosion energy than explosives in the charges of the remaining main wells additionally increases the efficiency of crushing of inclusions and host rocks and significantly simplifies the charging technology of these wells compared to charging them with combined explosive charges.

Clogging the bottom of additional wells to a height of 2 to 5 diameters of wells above the soil of lenticular inclusions of permafrost and loading these wells with explosive charges, the height of which is 2-5 diameters of wells below the roof of inclusions, eliminates the direction of the explosion in the direction of the host rocks, which have less resistance blasting. Therefore, despite the decrease in the mass of charges inside the inclusions, this also additionally increases the efficiency of their fragmentation. That is, the ends of explosive charges in additional wells must be separated from the soil and roof of inclusions at a distance of 2 to 5 diameters of the wells. At shorter distances, a directed action of the explosion towards the enclosing rocks is possible, and at large distances, a significant decrease in the mass of charges inside the inclusions is possible, which in both cases will lead to a decrease in the efficiency of crushing of inclusions. Smaller values of these distances correspond to larger diameters of wells and lower power of inclusions, and larger values to smaller diameters of wells and greater power of inclusions.

The use of additional water wells for clogging the bottom of the bottom part and charging them with explosive charges after freezing this water improves the clogging quality, since water turns into ice when freezing, increases in volume and more tightly closes the bottom of the wells, which further increases the efficiency of crushing lenticular permafrost inclusions .

Clogging the bottom of the additional wells with solid bulk drilling material followed by pouring water in them, the volume of which does not exceed the volume of the inter-granular space of the specified drilling material in the well, allows additional wells to be charged immediately after filling the water. In this case, by the time of the explosion, the water will freeze, the stall will turn into a monolith, expand and lock up the bottom of the well even better than pure ice, due to its greater density and strength. This further increases the efficiency of crushing lenticular inclusions of permafrost.

Figure 1 shows the exploded block of the ledge quarry in plan, figure 2 is a section along aa of figure 1.

The method is carried out by sequentially performing the following operations.

Taking into account specific conditions (properties of blasted rocks containing lenticular inclusions of permafrost, the height of the ledge and the angle of slope, the diameter of the wells and the maximum size of the conditioned piece in the blasted rock mass), parameters of explosive charges without explosive charges in similar conditions are determined without analogous conditions accounting for inclusions.

In accordance with the found values of the resistance along the bottom of the ledge, the distance between the wells in the row, the distance between the rows of wells, the length (depth) of the well, the angle of inclination of the downhole wells and the shape of the grid of wells, the main wells are drilled (vertical or deviated).

In the process of drilling the main wells, the presence, contour in plan, elevation of the roof and soil and the thickness of the lenticular inclusions of permafrost along the depth of each well are determined by changing the drilling speed, color and condition of the fracture products that are discharged to the surface.

Inside the contour in terms of lenticular inclusions of permafrost, additional downhole wells are drilled. These wells are drilled with the intersection of these inclusions, but not deeper than the main wells. At the same time, the marks of the roof and soil and the thickness of inclusions along the depth of additional wells are also determined.

Next, make loading and jamming of the main and additional wells.

When loading the main wells, the following options are possible:

1 - all the main wells, including those crossing the lenticular inclusions of permafrost, are charged with explosive charges corresponding to the properties of the rocks containing the indicated inclusions. This is the simplest and most profitable option from the point of view of technology and productivity of loading and stemming wells, as well as the installation of an explosive network;

2 - the main wells crossing the lenticular inclusions of permafrost are charged with combined explosive charges. Explosives with a higher concentration of explosion energy are placed inside these inclusions than explosives outside the inclusions. The remaining main wells are charged with explosive charges corresponding to the properties of the rocks containing lenticular inclusions. This option is more complicated and less productive than the first, but it provides great opportunities for regulating the degree of crushing throughout the exploded volume of rocks;

3 - the main wells crossing the lenticular inclusions of permafrost, are charged with explosive charges with a higher concentration of explosion energy than explosives in the charges of the remaining main wells. This option has the main advantages of the first two options, and the feasibility of its application is determined by the power of inclusions and economic factors.

In the process of loading the main wells, the installation of downhole blasting networks is carried out, which is carried out by the method adopted at this enterprise.

After loading the main wells, they are jammed.

Additional wells are charged with explosive charges, which are placed inside the lens-shaped inclusions of permafrost that they intersect.

Before loading additional wells, they are clogged to the bottom of the bottom to a height of 2 to 5 diameters of the wells above the soil of lenticular inclusions. Clogging can be done with water, and loading wells with explosive charges after freezing this water. It is also possible to clog the bottom of these wells with solid, solid bottom-hole material, and then pour water into the wells, the volume of which does not exceed the volume of the inter-granular space of the specified bottom-hole material in the well. In both embodiments, the quality of the stemming is improved, but the latter option is preferable, since loading can be done immediately after the bottomhole of the well.

After jamming the bottom of the additional wells, they are charged with explosive charges, the height of which is 2-5 diameters of the wells below the roof of the lenticular inclusions of permafrost.

Thus, the ends of the charges in additional wells are spaced from the soil and roof of lenticular inclusions at a distance of 2 to 5 diameters of the wells. Smaller values of these distances correspond to larger diameters of wells and lower power of inclusions, and larger values to smaller diameters of wells and greater power of inclusions.

As well as when loading the main wells, in the process of loading additional wells, the downhole blasting networks are installed, and at the end of loading, the clogging of the upper uncharged part of the additional wells is performed.

Any sequence of operations for loading the main and additional wells that is suitable for specific conditions is possible: after drilling; first, primary, and then additional wells;

for individual rows of wells; according to the types used for loading explosives in the case of using various explosives, etc. Clogging of the upper uncharged parts of the wells can also be carried out in a different sequence: immediately after the completion of charging each individual well with a charge of explosives, after the completion of loading of all the main and additional wells, or combined with time loading of individual groups of wells.

After the end of the clogging of all the main and additional wells, the surface blast network is installed, connected to the downhole blast networks and blasted borehole charges of explosives are one of the methods of blasting charges adopted in open cast mining.

Examples of the method

In all embodiments, overburden was blasted at a coal mine. The rocks are represented by siltstones, mudstones and strongly fissured sandstones. Lenticular inclusions of permafrost, which have a higher resistance to blasting than the enclosing rocks, lie inside these enclosing rocks.

The height of the step N was 12 m. The diameter of the wells d _well , equal to the diameter of the charge d _zar , was 160 mm (rotary drilling machine SBR-160). The direction of the downhole wells is vertical. The specific consumption of explosives (grammonite 79/21) for the host rocks is 0.46 kg / m ³ . Capacity 1 l.m. wells with a loading density of 850 kg / m ³ - 17.1 kg. The following parameters were adopted for the main wells: the distance between the wells in the row a is 7 m; the distance between the rows of wells b - 4 m; the shape of the grid of wells is staggered; well depth l _borehole - 13.5 m; _stemming length l _zab - 4.5 m; the length of the pole l _lane - 1.5 m; charge length l _zar - 9 m.

Example 1

The blasting unit drilled staggered along a grid of 7 × 4 m main wells 1-42 (Fig.1, 2). During their drilling, it was found that wells 3, 6, 7, 9, 10, 12-17, 19-24, 26-28, 30, 31, 34 and 35 intersect the lenticular inclusion 43 of permafrost (Fig. 2), the contour which in the plan of figure 1 is shown by a dashed line. At the same time, the depths of each well were determined elevation of the roof 44 (figure 2) and soil 45 inclusion 43 and its power.

Then, on the basis of the results obtained, additional wells 46-64 (Fig. 1) were drilled inside the circuit in terms of inclusion 43 with the intersection of inclusion 43, but not deeper than the main wells, and the marks of the roof and soil and the power of inclusion were determined by the depth of the additional wells.

After that, all the main wells were charged 1-42 with charges 65 (Fig. 2) of 79/21 grammonite, corresponding to the rock properties containing the lenticular inclusion 43, with the simultaneous installation of downhole blasting networks (not shown in the drawings) and jamming of the upper uncharged parts of 66 wells solid bulk blocking material (screening of the processing plant or others).

Additional wells 46-64 were charged with 67 grams of 79/21 charges, which were placed inside the lenticular inclusion 43, and at the same time, the installation of downhole blasting networks was carried out (not shown in the drawings). But before charging additional wells, their bottom part 68 was jammed with water to a height (distance) from 2 to 5 diameters of wells above the soil 45 of inclusion 43, and the loading itself began after water freezing. The height h of charges 67 in additional wells 46-64 was taken below the roof 44 of inclusion 43 also at a distance c equal to from 2 to 5 diameters of the wells. Smaller values of distances c corresponded to a lower switching power 43, and larger values to a higher switching power. In figure 2, the power of lenticular inclusion 43 is 1.84 m, 4.2 m and 6.2 m for additional wells 54, 55 and 56, respectively. Therefore, the distance from the well was 54 - 2d _borehole or 0.32 m, for wells 55 - 3,5d _borehole or 0.56 m and 56 wells -. 5d _wells or 0.8 m Similarly determined distances to other additional wells. Then, the top uncharged parts of 69 additional wells were clogged with the same solid loose blocking material (screening of the processing plant).

After the end of the stemming of all the wells, a surface explosive network was mounted (not shown in the drawings), connected to the downhole explosive networks and the explosive charges of explosives were blown up.

Example 2

The blasting of the block was carried out in the same way as in example 1, but the bottom part 68 (Fig. 2) of additional wells 46-64 (Figs. 1, 2) were clogged with solid loose material (screening of the processing plant). After that, water was poured into these wells, the volume of which was 30-40% of the volume of the specified bottom hole material in the well, i.e. did not exceed the volume of its intergranular space. Additional wells were charged with 46-64 charges of 67 grams of 79/21 grammonite immediately after jamming of their bottom part 68.

Example 3

The blasting of the block was carried out in the same way as in examples 1 or 2. However, the main wells 3, 6, 7, 9, 10, 12-17, 19-24, 26-28, 30, 31, 34 and 35 (figure 1 , 2) crossing the lenticular inclusion of 43 permafrost, charged with combined explosive charges (not shown in the drawings). An explosive with a higher energy concentration and heat of explosion (granulite AC-8) was placed inside the inclusion 43 than an explosive outside the inclusion (grammonite 79/21). The remaining main wells 1,2 4, 5, 8, 11, 18, 25, 29, 32, 33 and 36-42 were charged, as in examples 1 or 2, with charges of 65 grams of 79/21, that is, charges corresponding to the properties rocks containing a lenticular inclusion 43.

Example 4

The blasting of the block was carried out in the same way as in examples 1 or 2. However, the main wells 3, 6, 7, 9, 10, 12-17, 19-24, 26-28, 30, 31, 34 and 35 (figure 1 , 2), crossing the lenticular inclusion of 43 permafrost, charged with AC-8 granulite charges, which had a higher energy concentration and heat of explosion than gram 79/21, which charged the remaining main wells 1,2, 4, 5, 8, 11, 18 , 25, 29, 32, 33, and 36-42.

Sources of information

1. Technical rules for blasting on the surface. - M .: Nedra, 1972, p. 83.

2. Guidance on the use of the blasting method of loosening frozen and permafrost soils and moraines. - M.: Stroyizdat, 1972, p. 9.

3. Kutuzov B.N. Rock destruction by explosion. Textbook for high schools. 3rd ed., Revised. and add. - M.: MGI, 1992, p. 463.

Claims (8)

1. A method of blasting rocks with permafrost inclusions in open cast mining, including drilling downstream primary and secondary wells, loading them with explosive (explosive) charges, blocking wells, and blasting explosive charges, characterized in that during the drilling of the main wells in the presence of lenticular permafrost inclusions determine their contour in plan and the marks of the roof and soil of these inclusions by the depth of the wells, additional wells are drilled inside the contour with the intersection of the indicated inclusions, but not deeper than the main important, in this case, the marks of the roof and soil of inclusions are determined by the depth of additional wells, and when charging additional wells, explosive charges are placed inside intersected lenticular permafrost inclusions. 2. The method according to claim 1, characterized in that all the main wells are charged with explosive charges corresponding to rock properties containing lenticular permafrost inclusions. 3. The method according to claim 1, characterized in that the main wells crossing the lenticular inclusions of permafrost are charged with combined explosive charges, and explosives with a higher concentration of explosion energy are placed inside these inclusions than explosives outside the inclusions, and the remaining main wells are charged with explosive charges corresponding to the properties of rocks containing lenticular inclusions of permafrost. 4. The method according to claim 1, characterized in that the main wells crossing the lenticular inclusions of permafrost are charged with explosive charges with a higher concentration of explosion energy than explosives in the charges of the remaining main wells. 5. The method according to claim 1, characterized in that before charging additional wells, they bottom out their bottom to a height of 2 to 5 diameters of the wells above the soil of lenticular inclusions. 6. The method according to claim 1, characterized in that the additional wells are charged with explosive charges, the height of which is 2-5 well diameters below the roof of lenticular inclusions. 7. The method according to claim 5, characterized in that the bottom part of the additional wells is clogged with water, and charged with explosive charges after freezing this water. 8. The method according to claim 5, characterized in that the bottom part of the additional wells is clogged with a solid bulk drilling material, and then water is poured into these wells, the volume of which does not exceed the volume of the inter-granular space of the specified drilling material in the well.

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