SU1709095A1 - Method for working columnar pillars - Google Patents

Abstract

This invention relates to the underground mining of mineral deposits. The goal is to increase the efficiency of mining ore pillars by reducing the cost of drilling and blasting and the formation of final workings, reducing the ore depletion by rock and increasing the stability of the bottom workings. The space between the pillars is filled with a bookmark. In the tab, compensatory cavities are formed on the surface of the pillar by installing hollow blocks around the pillar perimeter. Under the whole transport pass. Drilling wells at the axial part of the pillar from the transport production. In the roof of the transport making, exhaust workings are carried out before the stockpiles of the ore pillar are crushed and a rock pillar is formed between them across the transport working. The reserves of the rear pillar are beaten off by blasting the wells from the non-perforated houses of their areas within the breed pillar. Before breaking the main reserves, the ore pillar is unloaded by blasting the upper ends of the wells in it. Stocks of recovered ore are released into transport production and the ore residues are dumped from the surface of the rock pillar by blasting uncharted sections of wells in the rock pillars. 4 hp f-ly, 3 ill.

Description

The invention relates to the mining industry and can be used in the development of supporting columnar pillars.

. The purpose of the invention is to increase the efficiency of mining ore pillars by reducing the cost of drilling and blasting and the formation of final workings, as well as reducing the dilution of ore by rock and increasing the sustainability of the workings of the bottom. FIG. 1 shows a vertical section of the pillar being worked; in fig. 2 is a section A-A in FIG. one; in fig. 3 is a section BB in FIG. one.

The method is carried out as follows.

The developed space between the pillars is filled with a bookmark. When forming each layer of the tab between the side surface of the pillar 1 and the filling material 2 along the entire perimeter of its cross section, a compensation cavity is formed, for example, air or water filled structures in the form of elastic shells, blocks of hardened foam or other hollow blocks 3 are used. (before the start of the laying) of the coating, for example by spraying.

the entire lateral surface of ceshdkoz is a porous material, for example, a quick-hardening foam based on urea-formaldehyde, urea or polyurethane resins. Both thickness of the layer formed by the above methods between the bookmark and the surface of the pillar is determined from the condition of placing the pillar without placing the blasted ore without clamping. For example, for a round pillar the thickness of this layer should be:

Jsjll

1) Ots, 2 Ku-1

where Ots is the pillar diameter;

Кр - coefficient of loosening of the broken ore of the pillar;

Ku - coefficient of compaction of the porous material of the cavity during the explosion.

In the cross section, the cavity may repeat the shape of the perimeter of the cross section, or it may differ from it. For example, with a circular cross-section of the pillar, it may take the form of a square, rectangle. In preparation for the development of the pillar, transport production 4 passes through the soil rocks in the soil, from which a well 5 is drilled in the axial zone of the pillar to its entire height, up to the top of the treatment space. The number of wells can be from one to several depending on the parameters of the rear sight and the diameter of the wells, their number should ensure the placement of the amount of explosives required for the destruction of the pillar. When the well is single, it is drilled along the axis of the rear sight, when several are drilled in the axial zone in the form of a parallel or divergent beam with a symmetrical arrangement relative to the axis of the rear sight.

Two sets of wells are also drilled to form outlet workings (slots) 6 in the roof of the transport exit. The wells for the formation of the outlet slits are drilled in the form of fans to the bottom of the rear pillar. The wells are positioned so that, after their explosion, wells 5 were not disturbed, and under the base of the pillar being worked across the transport workings, the rock pillars 7 were formed between the exhaust workings with a cross section in the form of a trapezium.

The lower side of its trapezoidal section is placed on contact with the base of the ore pillar.

After drilling these sets of wells, the upper ends of the wells 5 are charged and blown up, thereby unloading the ore pillar from the rock pressure.

Due to the presence of the perimeter compensation space, this explosion achieves maximum preservation of the integrity of the roof over the whole and high compliance of the resulting layer 8 of destroyed ore, which makes it possible to relieve the main part 9 of the pillars from the pressure of the roof rocks by transferring it to the bookmark. Since the compensation space

being filled with the structures described above, then exploded in the upper part, the pillar of the ore does not descend along the cavity below the level of the explosion.

Next blow up kits

rock wells below the base of the pillar being worked to form the outlet slots 6. The rock that is being beaten off is shipped. The forming pedigree pillar 7, with its ends, rests on an array of side walls of the transport excavation and serves as a support for the ore pillar being worked out. The pillar parameters are calculated from the condition of maintaining stability only on the weight of the ore pillar being worked,

since the latter is unloaded from the pressure of the overlying strata at the time of introduction into the work of the breed.

After the formation of outlet slots and rock support pillars, the axial bundle of wells 5 is charged and the safety of the rock pillars 7 is ensured by undercharging wells within it. In the explosion, due to the presence of a shell of porous and easily destructible material,

playing the role of a perimeter compensation cavity, as well as a symmetric axial arrangement of charges, the destruction of the rear sight is relatively easy, with less energy and

less explosion impact on the bookmark. At the same time, the highly destructible porous structures, which form the shell along the perimeter of the pillar section, are destroyed during the explosion, are displaced to the surface.

bookmarks, cover this surface and compacted, creating a damping layer that reduces the impact on the surface of the bookmark during the explosion and the release of ore. After the ore has been released, this compacted layer of material or structures protects the tab from the effects of the atmosphere.

Claims (5)

The exploded ore mass 10 is released into transport production and immersed either simultaneously from both slots or sequentially. At the final stage, the ends of the unexploded sections of wells 5 are charged at the level of the upper platform of the cross-section of the rock pillar 7 and exploded, which ensures the discharge and discharge slots of the ore that is stuck there. Claim 1. Method of mining the column ore pillars, including laying the space developed between the pillars, forming a compensation cavity in the pillar at the pillar, carrying out the entire transport output, drilling, / charging and blasting wells, carrying out discharge workings with forming the pillar pillar and releasing reserves repulsed ore into transport production, characterized in that, in order to increase the processing efficiency of ore pillars by reducing the cost of drilling and blasting and education exhaust workings, as well as reducing the dilution of ore by the rock and increasing the stability of the workings of the bottom, the formation of a compensation cavity between the filling and the whole is carried out around the perimeter of the rear sight, drilling of wells takes place in the axial zone of the rear sight, exploding //; /// of the upper ends of the wells in it. exhaust workings are made in the roof of the transport workings, while the formation of the rock pillar between them is carried out across the transport workout, and the workings of the exhaust run to the breaking of ore stockpiles. 2. The method according to claim 1, wherein that the blasting of wells in the ore target; ke is carried out with undercharging of well sections within the rock pillars. 3. A method according to claim 1, characterized in that after the release of broken ore, ore residues are dumped from the surface of the pillar pillar by blasting the ends of the undercharged sections of the wells in the pillar pillar. 4. Method pop. 1, characterized in that the formation of a compensation cavity around the ore pillar is carried out by installing hollow blocks. 5. A method according to claim 1, characterized in that the drilling of wells in the pillars of the ore is produced from the transport generation. /// 7 / ////////// Ig.1 (Rig. 2 //.J