RU2292010C2 - Method for blasting of behches under shelter and mechanical device for its realization - Google Patents

Abstract

FIELD: mining industry, in particular, mining of hard rocks in hindered conditions when it is necessary to prevent scattering of the blasted rock mass.

SUBSTANCE: the mechanical device for long-term locking of detonation products has a cylinder with an axial cavity and a tapered expansion. The tapered expansions are made on both-ends of the cylinder and at least three slots are made in each of them. A spacer cone is inserted in the lower tapered expansion, it is coupled to a thick-walled tube freely passing through the axial duct of the tapered plug inserted in the upper tapered expansion. The tapered plug is additionally provided with a recess closed with a hinged cover and with an installation loop with a flexible coupling. The method for blasting of benches under a shelter consists in drilling of blast holes, their charging, tamping, sheltering of the bulk to be blasted, blasting of the rocks and removal of the shelter. Tamping of the holes is made by installation of mechanical devices for a long-term locking of the detonation products and their preliminary wedging in the hole. The mechanical devices for a long-term locking of the detonation products are lowered in the hole down to the required lever and installed their. The initiating pulse conductor is placed in the recess in the tapered plug of the mechanical devices and closed with the cover. After that the shelter in the form of a mat composed of inter connected automobile tires is placed on the high wall and the bench surface, and fastened by the anchors installed in shallow holes with the aid of ropes and thin chains. Part of the mat (1-2 types) should remain on the bench bottom. After that the mechanical devices for a long-term locking of the detonation products are connected to the shelter by a flexible coupling, the conductors of the initiating pulse are extracted from them, the blasting network is installed above the shelter, and the sheltered bench is blasted. After the blast the shelter is removed with the aid of a bulldozer for the ropes or chains removed from the anchors, the mechanical devices for complete locking of the detonation products are removed at the same time.

EFFECT: provided breaking of rocks without scattering of pieces to the high wall slope with a long-term locking of the detonation products in the charge cavity.

5 cl, 4 dwg

Description

The invention relates to the field of mining, in particular to the development of strong rocks on a day surface in cramped conditions, when it is necessary to reduce the spread of blasted rock mass - when mothballing temporarily idle sides of deep quarries, blasting near cyclic-flow technology complexes, posting sides of deep rock excavations in road construction, etc.

Known methods of blasting rocks with the installation over the blasted surface of special shelters of various designs or filling the ledge surface with soil, automobile tires in bulk in several layers to reduce the expansion of pieces of rock [1]. Their main disadvantages are the prevention of pieces flying apart only from horizontal platforms, while a significant outburst of rock mass comes from the escarpment of an exploding ledge.

The closest to the essence of the problem is the method of blasting under the shelter in the form of a pile of worn out automobile tires that can pass the gases of the explosion, thereby reducing the impact on the shelter. A significant total mass of tires laid in several layers, allows you to achieve the necessary loading of the blasted array. The inertial resistance of the rock mass, reinforced by the mass of the shelter, balances the force of the explosive shock [2].

The disadvantage of this method is the large expansion of pieces of blasted rock mass under the escarpment of the ledge, since only a horizontal surface is covered, as well as the difficulty in mounting and, especially, dismantling the shelter from individual tires, when individual tires have to be removed from the bulk of the rock mass.

There are a number of designs of locking faces in the form of plastic plugs, wooden and concrete wedges [3]. Their main disadvantage is low efficiency.

It is also known locking gas-dynamic device, which is a cylinder of plastic material with an axial channel having a two-conical profile [4]. The impact of the explosion gases on the cone of the axial channel with a large angle at the beginning of the device presses it against the walls of the well, and the outflow of detonation products through the second conical narrowing of the axial channel with a small taper angle allows you to delay part of the detonation products in the well and thereby increase the area of the destructive effect of the explosion by 30-40%.

The disadvantage of this device is the delay of only part of the detonation products in the charging cavity, as well as the inability to reuse.

The technical problem to which the invention is directed is to increase the safety of blasting operations by reducing the expansion of pieces of rock and increasing the efficiency of explosive crushing of rocks by locking the detonation products in the charging cavity until the surrounding rock is completely destroyed by a reusable mechanical device.

The problem is achieved in that in the method of blasting ledges under the shelter, including drilling blast holes, loading, jamming, covering the blasting volume, blasting rocks and cleaning the shelter, according to the invention, blocking wells is performed by installing mechanical devices for long-term locking of detonation products and their preliminary wedging in the well.

Mechanical devices for long-term locking of detonation products are lowered into the well to the desired level and installed there, the initiating impulse conductor is placed in a recess in the conical plug of the mechanical devices and closed with a lid, after which a shelter is placed in the form of a mat composed of interconnected between car tires, and fix it to anchors installed in shallow wells, using ropes or thin chains, while at the bottom of the ledge should remain part of the mat once erom 1-2 tire; after that, mechanical devices for long-term locking of detonation products are connected by a flexible connection to the shelter, the initiating impulse conductors are extracted from them, the explosive network is mounted on top of the shelter, and the covered ledge is blown up.

Shelter cleaning after the explosion is carried out using a bulldozer for the ropes or chains removed from the anchors, while mechanical devices for long-term locking of detonation products are also removed.

This goal is also achieved by the fact that in a mechanical device for long-term locking of detonation products, including a cylinder with an axial cavity and a conical extension, according to the invention, conical extensions are made at both ends of the cylinder and at least three slots are made in each, a spacer cone is inserted into the lower conical extension connected to a thick-walled pipe freely passing through the axial channel of the conical plug inserted into the upper conical extension,

The conical plug is additionally equipped with a recess, a closing hinged lid, and a mounting loop with a flexible connection.

It is the claimed embodiment of the device that allows you to shelter the detonated ledge without damaging the blast network, and to explode borehole charges with non-flying jamming, thereby solving the problem. This allows us to conclude that the claimed invention is connected by a single inventive concept.

The inventive method of blasting ledges under the shelter is carried out using a mechanical device for long-term locking of detonation products, schematically shown in the drawings.

Figure 1 presents a side view of the shelter; figure 2 is a view along arrow a in figure 1; figure 3 shows the design of a mechanical device for long-term locking of detonation products after mounting it in the well (node B in figure 1); figure 4 - node In figure 3, representing an embodiment of the manufacture of the cover.

The blast ledge 1 is drilled with blast holes 2 and at a distance from the block, shallow (2-4 m) wells are drilled into which the anchors 3 are installed using eyelets 4. The anchors can be made from pieces of thick-walled pipes, for example, from used drill rods cone drilling machines. After that, blast holes 2 are charged. Blast holes 2, which are extreme from a lateral slope, are charged with a reduced bulging charge, in which the explosion energy is sufficient to displace the rock toward 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 it crushing with buckling, without scatter [5].

After charging blast holes 2, they install mechanical devices for jamming wells.

Each device includes a cylinder 5 made of metal or plastic mass with a diameter 4-8 mm smaller than the diameter of the well, with an axial cavity 6. On both sides, the cylinder 5 has conical extensions 7 with slots 8. A hollow expansion cone 9 is inserted into the conical extensions 7 below connected to a thick-walled pipe 10 provided with a nut 11, made of metal, and on top of a conical plug 12 with an axial channel 13 and a recess 14 made of metal or plastic. Mounting loop 15 with flexible coupling 16 and a hinged lid 17 with a locking device 18 are mounted on the conical plug 12.

On the surface of the block, mechanical devices for long-term locking of detonation products are assembled into a structural element. To do this, insert a hollow expansion cone 9 with a thick-walled pipe 10 into the lower conical extension 7 of the cylinder 5, pass the thick-walled pipe 10 through the axial cavity 6 until it exits the cylinder 5, and through the axial channel 13 put on a conical plug 12 with the bow of the mounting loop 15. Then tighten the nut 11, pulling the conical tube 12 and the expansion cone 9 towards the contact with the conical extensions 7 by a thick-walled pipe 10 towards each other.

After the device is assembled, a conductor of an initiating pulse 19 (wires from an electric detonator, a waveguide of a non-electric system or a detonating cord) is passed through a thick-walled pipe 10 and, using a mounting loop 15, the device is lowered into a well 2 to a level not exceeding the length of a person’s outstretched hand. The conical plug 12 and the expansion cone 9 are pulled together with a nut 11 until they bore the cylinder 5 into the borehole walls using conical extensions 7 and slots 8. After that, the initiating pulse conductor 19 is placed in the recess 14, closed with a lid 17 and locked with a lock 18. Mechanical device for long-term locking of the detonation products is ready for operation and step 1 is prepared for explosion. On the sole of the ledge 1, a shelter 20 is assembled from individual worn tires 21, the diameter of which is selected based on the height of the ledge so that the bend of the mat along the upper and lower edges of the ledge passes at the junction of the individual tires. The tire size range of heavy dump trucks, for example, BelAZ type is quite wide - from 1.6 m for BelAZ-540 to 3.1 m for BelAZ-7519 [6]. To connect the tires in them, crosswise install chains or ropes 22, the exits of which through the tread are equipped with connecting elements 23, for example, hooks and earrings. The connection of the connecting elements 23 through chains or ropes 22 has two purposes. Firstly, when loads occur at the time of the explosion, they are transferred to chains or ropes 22, balancing the deformation of the tires 21. Secondly, the size of a piece of rock that can be ejected through the inner hole of the tire 21, reaching 0.6 m for tires, is reduced by four BelAZ-540 and 1.3 m for tires BelAZ-7519. Shelter 20 is collected either immediately over the entire width of the covered volume, or in the form of separate strips along the length of the slope and the surface of the ledge, and then several bands are connected after being placed on the covered volume in a single shelter, using auxiliary mechanisms, for example, car towers.

The collected shelter 20 with the help of a truck crane is placed on the ledge 1, leaving on the sole of the ledge a part of the mat with a length of 1-2 tires. Using ropes or chains 24, the shelter is fixed to the anchors 3.

After placing the shelter on the ledge, all the equipment and workers are removed outside the danger zone and proceed with the installation of the explosive network. Before starting the installation of the explosive network, the detonator tilts, passes a hand through the hole in the tire, if necessary, drops to the knee on the tire, turns the locking element of the device 18, made, for example, in the form of a lamb, lifts the cover 17 using a chamfer on the edge of the cover or a hole in it (descriptions are not shown in FIG. 3), takes out the initiating element and unwinds it in length.

After that, the explosive network is mounted over the shelter and an explosion is made.

After detonation of the explosive charge in the charging cavity, the pressure of the detonation products sharply increases to tens of thousands of atmospheres and a dynamic impact of gases occurs on the expansion cone 9. Due to the large internal surface of the cone, the magnitude of the force perceived by it is significant, which leads to its additional pressing into the lower conical expansion 7 and the final jamming of the cylinder 5 in the well 2. The thick-walled pipe 10 thus freely passes through the axial channel 13, without violating the position of the upper conical plug 12, shedding the upper part of the cylinder 5 into the walls of the well 2.

This is the position of mechanical devices for jamming wells remains until the breakthrough of detonation products from the charging cavity into the atmosphere through cracks in the destroyed array. Providing long-term isolation of the charging cavity, devices contribute to a more complete course of secondary reactions in detonation products and, accordingly, increase the energy of the explosion; this is especially important for modern coarse-grained explosives such as granulites and grammonites, in which a significant proportion of the energy is released during secondary reactions.

In a successive explosion of loosening charges, the bulk of the explosion energy is spent on crushing the rocks in the ledge 1 and the displacement of the gas-permeable shelter 20. And the first part of the shelter located on the slope of the ledge begins to shift, since the rock swelling begins precisely from the slope. Due to the use of 2 bulging charges in the extreme wells, the first, most powerful, rock mass strike at shelter 20 is mitigated - rock mass swells with movement, but without expansion. This allows the shelter from the tires to smoothly deform on the escarpment of the ledge due to the elasticity of the tires 21 themselves, the connecting elements 22 and pulling up the tires 21 from the sole.

Together with the expanded rock mass, the shelter creates a buffer layer, damping the explosion of the following rows of wells, similar to blasting in a clamp onto an unmade rock mass, and preventing pieces from flying out through the gaps in the shelter 20. The elasticity of the shelter from the tires due to the elasticity of the tires 21 themselves and the ligaments 22 and 24 from ropes or chains between them during expansion of the blasted rock it does not allow separate pieces to come off the total mass, the loosened rock mass is tightly wrapped in mat and held in a compact state.

Shelter 20, swelling on the slope, will pull the lower tires 21 located on the bottom of the ledge, which will provide the ability to shift the lower part of the shelter to dampen the load and at the same time will not allow pieces of rock mass to fly out from under the shelter. At the same time, a load will also arise on the horizontal part of the shelter, but anchors 3 will prevent its displacement through ropes or chains 24. The eyes 4 will prevent the ropes or chains 24 from slipping. Therefore, the shelter will begin to slide along the rock mass and, due to friction forces, will provide additional resistance to its movement. With a sufficiently long length of the ropes or chains 24 they, with a sharp tension, also absorb the jerk for shelter. In addition, each individual tire 21 of the shelter 20 will deform in different directions under load, while also mitigating the overall impact load of the explosion on the shelter. The inertial resistance of the compact mass of the rock, reinforced by the mass of the shelter, balances the force of the explosive shock.

The height of the rock toss with shelter 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. Given that the coefficient of loosening of rocks during blasting in the clamp is 1.05-1.1, and the height of the blasted ledges is 10-15 m, the reserve length of the shelter is 1-2 tires (depending on their diameter, it is from 1.6 to 6 m) on the bottom of the ledge it will be enough so that it does not expand beyond the limits of the rock mass being blown up.

After the explosion, the shelter with the help of ropes removed from the anchors is pulled from the surface of the rock mass with a bulldozer, while also removing mechanical devices for clogging the wells for flexible connection 16. In case of difficulties, it is disconnected and partially removed from the rock mass. For the next explosion, the same ropes or thin chains are used, shortening them by the desired size. In the future, the wells, after removing the anchors, are drilled to the design depth and used as blasting ones.

After removing the mechanical devices for jamming wells from the rock mass, they are disconnected from the shelter 20, the nut 11 is unscrewed and the cone 9 and plug 12 are successively removed from the cylinder 5, the cutting parts 7 of the cylinder 5 are calibrated by the diameter of the well, and the device is reassembled for reuse.

Thus, the inventive method of blasting ledges under the shelter and a device for its implementation provides rock breaking without scattering pieces under the slope of the ledge with long-term locking of the detonation products in the charging cavity, thereby allowing to solve the problem.

Information sources

1. Instructions for the production of blasting with protective shelters. M .: CPES, 1987 (prototype).

2. Guide to shelters that prevent or reduce the flight range of fragments during blasting in cramped conditions. M .: CBTI, 1969.53 s. (prototype).

3. Mindeli E.O., Demchuk P.A., Aleksandrov V.E. Clogging holes. - M .: "Nedra", 1967. - 152 p.

4. Paramonov G.P. et al. Study of the effectiveness of the use of gas-dynamic locking devices as stemming downhole charges // Sat. "Explosive business" No. 91/48. The development of the theory and practice of explosives. M., 1998. With 214-221 (prototype).

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

6. Reference. Open cast mining / K.N. Trubetskoy, M.G. Potapov, K.E. Vinnitsky, etc. - M.: Mining Bureau, 1994. - 590 p.

Claims (5)

1. A mechanical device for long-term locking of detonation products, including a cylinder with an axial cavity and a conical extension, characterized in that the conical extensions are made at both ends of the cylinder and at least three slots are made in each, a spacer cone connected to a thick-walled is inserted into the lower conical extension a pipe freely passing through the axial channel of the conical plug inserted into the upper conical extension. 2. The mechanical device according to claim 1, characterized in that the conical plug is additionally equipped with a recess, a hinged lid, and a mounting loop with a flexible connection. 3. The method of blasting ledges under the shelter, including drilling blast holes, loading, jamming, covering the blasting volume, blasting rocks and cleaning the shelter, characterized in that the blocking of the wells is performed by installing mechanical devices for long-term locking of detonation products according to claim 1 and their preliminary wedging in the well. 4. The method according to claim 3, characterized in that the mechanical devices for long-term locking of detonation products are lowered into the well to the desired level and installed there, the initiating pulse conductor is placed in a recess in the conical plug of the mechanical devices and closed with a lid, after which it is sloped and the surface of the ledge place a shelter in the form of a mat composed of interconnected car tires, and fasten it to anchors installed in shallow wells, using ropes or thin chains, while on the sole of the mouth pa must remain part of the mat size tires 1-2, thereafter the mechanical locking device for long products of detonation is connected with a flexible coupling cover, which is removed from the conductors of the initiating pulse produces explosive assembling network over shelter and blow covered ledge. 5. The method according to claim 4, characterized in that the shelter after the explosion is carried out using a bulldozer for the ropes or chains removed from the anchors, while mechanical devices are also removed for completely locking the detonation products.

Images