RU2236588C1 - Method for tretment of high shelves - Google Patents

Abstract

FIELD: mining industry.

SUBSTANCE: method includes drilling, charging of blast-holes, their detonation and following extraction of detonated rock solids. Method allows to prevent wide spread falling of rock pieces during detonation by covering of detonated rock layer, and letting ore pieces fall from steep rocks during extraction is performed onto light woven mat.

EFFECT: excluded wide spread fall of ore mass pieces during explosive operations and extraction of high steep rock shelves.

3 cl, 4 dwg

Description

The invention relates to the field of mining, in particular to the development of strong rocks in cramped conditions, when it is necessary to exclude the spread of the blasted rock mass under the escarpment of high ledges - when mothballing temporarily idle sides of deep quarries, posting the sides of deep rock excavations in road construction, etc. .

So, in the deep quarries of Yakutia that mine diamonds, there is a significant complication of organizing continuous cargo transportation of mining ledges with the surface while mining in the intermediate and reconstructed contours, which is due to the overburden of spiral exits and berms of blasted rock mass during mass explosions to the height of the ledge in the zone spacing board. In this regard, the rhythm of the work of quarries for ore mining is disrupted, and downtime for organizational reasons is increasing. The volume of overburden dumped into the intermediate circuit is 8.3 m ³ with 1 m ^{2 of} exposed surface of the side and reaches 8% of the total volume of reconstruction work [1]. It is necessary to find such methods of posting the sides so that the blasted rock mass remains at the place of the explosion, and the rock expansion from the slope of the ledge to the side of the worked out space is minimal. The method of blasting in a clamped medium on a retaining wall from the side of the escarpment of the ledge, excluding the expansion of pieces from the escarpment of the ledge, is unacceptable due to the lack of sufficient width of the sites.

The most common way to reduce the expansion of pieces of rock during explosive crushing is to install special shelters of various designs over the blasted surface [2]. Their main disadvantages are the prevention of pieces flying apart only from the site of the ledge, while a significant ejection of rock mass comes from the slope of the exploding ledge.

A known type of shelter in the form of mats made from waste anchor chains, this design has a working body, perceiving the impact of the explosion, in the form of links of the anchor chain that can pass the gases of the explosion, thereby reducing the impact on the shelter. The elasticity of the chain mats during the expansion of the rock from the explosion does not allow tearing individual pieces from the total mass, the loosened rock mass is tightly wrapped around the mat and kept in a compact state. The inertial resistance of the compact mass of the rock, reinforced by the mass of the shelter, balances the force of the explosive shock. This explains the complete absence of scattering of individual pieces, and the whole loosened rock mass is thrown up by an explosion 1-5 m up and falls back [3].

The closest to the essence of the problem being solved is the method of explosive mining of ledges, according to which a high ledge is divided into layers, blast holes are drilled in each layer, they are charged, and the extreme row of blast holes are charged with a reduced charge, blasting and subsequent excavation of the blasted rocks are carried out [4 ].

The disadvantage of this method is the large expansion of pieces of blasted rock mass under the escarpment of a ledge.

The object of the invention is the elimination of the expansion of pieces of rock to the escarpment of high ledges during blasting and excavation of rock mass.

The problem is achieved in that in the method of mining high ledges, according to which the separation of the high ledge into layers is carried out, blast holes are drilled in each layer, they are charged, and the blast holes that are extreme from the side slope are charged with a reduced charge, blasting and subsequent excavation of the exploded rocks , according to the invention, the height of the layers during their separation is performed not exceeding the scooping height of the extraction equipment, each layer being prepared for explosive loosening and excavation, for why, on the side slope of the high ledge at the level of the base of the blast layer, anchors are installed, connected to the top with a carrier link and the upper part of the lightweight woven mat is fixed on it, the lower part of which is fixed with a weighting agent on the bottom of the lower layer, then in the blast layer they drill and charge blast holes, a cover made of gas-permeable heavy chain mats is placed on all open surfaces of the blasted section of the layer to prevent pieces of rock from scattering during the explosion, while the side slope shelter dipped under a light wicker mat and produce a layer explosion, after the explosion, the shelter is removed and a blasted rock mass is excavated with an end face, while preparing for the explosion of the next underlying layer of a high ledge from under the light wicker mat, the accumulated rock mass is selected, freeing up space for a new cycle of work, reduce its length to the height of the layer being prepared for the explosion and fix the upper part of the lightweight woven mat webs on the carrier link of the anchors newly installed at the sole level of the explosion layer.

Shelter of the end surface of the blasted section of the layer is performed by a retaining wall of uncleared rock mass.

Sheltering of the end and upper surfaces of the blasted section of the layer is performed by a mobile installation for localizing the explosion.

Figure 1 schematically shows the implementation of the method when performing a shelter from a gas-permeable heavy chain mats; figure 2 - the same when covering the end part of the exploding layer of rock mass; figure 3 is the same when covering the upper and end parts of the explosive layer with a mobile installation; figure 4 is a section aa in figure 1.

The method of mining high ledges is as follows.

A high ledge on a quarry or road recess in rock formations is divided in height into layers 1, not exceeding the height of digging of excavation equipment (see Figs. 1-3), and each layer is prepared for explosive loosening and excavation. First, it is prepared for excavation, for which purpose, on the side slope 2 of the blast layer 1, at the level of the sole 3, anchors 4 are installed, connected on top of the carrier link 5, and the upper part of several lightweight woven mat 6 connected by the side parts is fixed on it, made, for example, of propylene fibers, such mats are widely used in foreign practice for sheltering explosive areas [5]. The lower part of each web of lightweight woven mat 6, the width of which corresponds to the width of the blasting block of layer 1, is fixed with a weighting agent 7 on the sole 3 of the lower layer 1 of the high ledge, and due to this, it is spread along the entire length of the side slope 2 of the high ledge, adjacent to it below the anchors 4 close. It creates a kind of soft flattened bag with an open receiving opening, while in width it is one or two blades ahead of the blasting unit. This completes the preparation for the excavation of rocks of layer 1.

Then layer 1 is drilled with blast holes 8 (see figure 4) and charge them. In this case, blast holes 8, which are extreme from the lateral slope, are charged with a reduced bulging charge, in which the explosion energy is sufficient to displace the rock towards the free surface, and this displacement will cover the entire thickness of the rock between the charge and the surface and will be accompanied by crushing with bulging, without scatter [6].

After charging blast holes 8, layer 1 is prepared for explosion, for this purpose, a gas-tight shelter from heavy chain mats 11 made, for example, from fragments of anchor chains, is placed on all open surfaces of the blasting area of layer 1 — the upper part 9, the end part 10 and the side slope 2 laying them, for example, using a crane so that the edges of the mats are located 1.5-2 m further than the edges of the blasted section of the layer (see figure 1); or as a shelter for the end part 10 of the blasting layer 1, use a retaining wall from the uncleared rock mass 12 (see figure 2); or as a shelter for the upper part 9 and the end part 10 of the explosive layer 1, a mobile installation is used to localize the explosion 13, for example, similar to that described in [7] (see Fig. 3). In all cases, the lower edge of the heavy chain mat 11 on the side slope 2 of the blast layer 1 is located below the upper edge of the canvas lightweight wicker mat 6 (see figure 4).

In an alternating explosion of loosening charges, the main part of the explosion energy is spent on crushing rocks and displacing gas-permeable heavy chain mats 11, rock mass 12 or shelter elements of the blast containment unit 13. The elasticity of chain mats during rock expansion does not allow individual pieces to break away from the total mass , the loosened rock mass is tightly wrapped around the mat and held in a compact state by it. The inertial resistance of the compact mass of the rock, reinforced by the mass of the shelter from the chain mats, balances the force of the explosive shock. The height of the rock toss with shelter from gas-permeable heavy chain mats 11 depends only on the thickness of the blasting layer and the coefficient of loosening of the rock, since the amount of rock swelling after loosening depends on the latter. Separate pieces of rock from under the heavy chain mat 11 on the side slope 2 can slide under the web of the lightweight wicker mat 6 into the gap formed by the anchors 4, and slide smoothly under the web of the lightweight wickerboard mat 6 along the side slope 2, accumulating at the weighting material 7. When this due to friction on the surface of the canvas lightweight woven mat 6 and the side slope 2 eliminates spasmodic movement of pieces on the slope, leading to their distant fall.

After the explosion, the shelters are removed from the blasted part of layer 1 and the excavation of the blasted rock mass begins with an excavator or loader at a pile height equal to the scooping height, which will provide significantly less rock mass mobility and reduce the number of pieces of rock sliding under a lightweight woven mat 6. Direction of layer mining 1 is shown in FIG. 1 by an arrow.

After excavating the blasted rock mass, a retaining wall from the uncleared rock mass can be left, and the method will develop according to the scenario of FIG. 2 - a shelter from gas-permeable heavy chain mats 11 is placed only on the upper part 9 and the side slope 2 of the blast layer 1. If the rock mass completely removed, the method will develop according to the scenario of figure 3 - a shelter from gas-permeable heavy chain mats 11 is placed only on the side slope 2 or according to the scenario of figure 1 - a shelter from gas-permeable heavy chain mats 11 is placed on all the free surfaces of layer 1. With all variants of the development of work on this layer, again on the side slope 2 of the exploding layer, anchors 4 are installed at the level of the sole 3, they are joined on top by a carrier link 5 and the upper part of the next one or two sheets of lightweight woven mat 6 is fixed on it, then connect their lateral part with the previously installed canvases, while keeping ahead of the shelter of the side slope 2 relative to the blasting section of layer 1. Then the whole cycle of work on blasting and excavation of this layer 1 is repeated.

In preparation for the excavation of the next, underlying layer 1 of the high ledge, on the sole of the high ledge, weights 7 are lifted, for example, with a crane and a rock mass is selected, for example, with a bucket loader, freeing up the space under the light woven mat 6 for a new cycle of work. Then the upper part of the canvases of the light wicker mat 6 is removed to the height of the layer prepared for the explosion and the process of fixing it on the anchors 4 is repeated with the above-described technique. When blasting the lowest layer of a high ledge, the shelter of the side slope 2 of the blasted rock layer is carried out only by a heavy chain mat 11 (see figure 3).

Thus, the inventive method of mining high benches provides layer-by-layer breaking and excavation of rocks of high benches with an end face without spreading pieces to the escarpment of the ledge, thereby allowing to solve the problem.

Sources of information

1. Androsov A.D. Development of technology for reconstruction of deep quarries in Yakutia. - Novosibirsk: Nauka, 1991 .-- 103 p.

2. Instructions for the production of blasting with protective shelters. M .: CPES, 1987.

3. Avdeev F.A., Yuzhakov S.V. A new type of protection against the expansion of pieces of rock during explosions. // Explosive business No. 61/18. - M .: Nedra, 1966 .-- S. 218-223.

4. The method of explosive mining of ledges: Auth. testimonial. USSR No. 1707201, E 21 C 41/26, E 21s 37/00, 1992 (prototype).

5. Averyanov V.I., Dobrynin A.A. Blasting operations near urban and industrial facilities // Mining Journal. 1999, No. 11. - S. 78-80.

6. Demidyuk G.P. Application of the energy principle to the calculation of borehole charges in quarries. // Explosive business No. 62/19. - M .: Nedra, 1967 .-- S. 36-51.

7. Patent of the Russian Federation No. 2163347, MKI 7 F 42 D 5/045.

Claims (3)

1. The method of mining high ledges, according to which the separation of the high ledge into layers is carried out, blast holes are drilled in each layer, they are charged, and the blast holes which are extreme from the side slope are charged with a reduced charge, blasting and subsequent excavation of the blasted rocks are performed, characterized in that the height of the layers during their separation is performed not exceeding the scooping height of the extraction equipment, each layer being prepared for explosive loosening and excavation, for which, on a side slope of a high ledge, at the level of the sole of the blast layer, anchors are installed, connect them on top of the carrier link, and the upper part of the lightweight woven mat web is fixed on it, the lower part of which is fixed with a weighting agent on the bottom of the lower layer, then in the blast layer they drill and charge blast holes on all open surfaces of the blast layer section place a shelter made of gas-permeable heavy chain mats to prevent the pieces of rock from scattering during an explosion, while the side slope shelter is lowered under a light wicker mat and the layer is blown up, after the blast, the shelter is removed and the blasted rock mass is excavated with an end face, while preparing for the explosion of the next underlying layer of a high ledge from under the light wicker mat, the accumulated rock mass is selected, freeing up space for a new cycle of work, reducing its length by the height of the prepared to the explosion of the layer and fix the upper part of the canvases of the light wicker mat on the bearing connection of the anchors, newly installed at the level of the sole of the explosive layer. 2. The method according to claim 1, characterized in that the shelter of the end surface of the detonated section of the layer is performed by a retaining wall of uncleared rock mass. 3. The method according to claim 1, characterized in that the shelter of the end and upper surfaces of the blasted section of the layer is performed by a mobile installation for localizing the explosion.

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