RU2715503C1 - Method for open-underground development of flat-lying formations - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining for open-underground development of flat-lying minerals and can be used in distribution of perennial permafrost for extraction of mineral resources using technology of deep development of formation. Proposed method comprises preparation of site for extraction complex and its assembly, extraction of mineral by means of cleaning chambers by means of parallel workings, and underground working. Site preparation for excavation works is performed by rifling of cut trench across strike of formation. At a distance from the trench of not more than depth of the excavation of the complex, the underground mine is drilled by the formation dip. Extraction of mineral from cleaning chambers is performed along the strike of the formation until the chamber with the underground mine opening intersects and the chambers are filled with a hardening solution.

EFFECT: improving development efficiency of a flat-lying mineral deposit.

6 cl

Description

The invention relates to mining for open-underground mining of shallow seams of minerals and can be used in the field of permafrost for excavation of minerals using the technology of a complex of deep development of the reservoir.

There is a method of open-underground mining of a shallow coal seam of medium power, including preliminary preparation of the front of the sewage treatment works by constructing a working platform on the ledge of the side of the cut along the strike line at the soil level of the developed seam, installing on the working site of a deep mining complex, coal mining by this complex aside from the work site by conducting parallel workings of a rectangular cross-section with the left pillars, the issuance of beaten coal for the development of the work site and p Booting in his vehicle or storage in a stack (see. RU №2436953, cl. E21C 41/00, publ. 20.12.2011). In this case, at first, the opened formation is divided by barrier pillars into excavation blocks, each excavation block is conventionally divided into the mouths of the workings and pillars, placing the pillars between the mouths of the workings. Treatment work begins with the first development of the first excavation unit with an anchor roof. Then, the second excavation is carried out in a similar manner, then the pillar between them is removed, the third excavation is carried out and the pillar is repaid between the second and third excavations, and so on to the opposite edge of the excavation block. The mining of the excavation blocks is carried out in the same order as the order of the workings in the block, and the width of the pillar is taken approximately equal to the width of the excavation.

The disadvantages of the known solutions are losses in the bowels of the mineral in the barrier pillars and the limited depth of the mine field from the side of the slope with the maximum conveyor length of the complex. A large area of exposure of the roof, partially fixed by a lightweight type of lining, increases the risk of manifestation of rock pressure and narrows the scope of the method.

According to the method of extraction of mineral reserves in the redeemable sides of the quarry (see RU No. 2205955, cl. E21C 41/26, publ. 10.06.2003), including the formation of a working platform on a ledge with a mineral outlet to its slope, and extraction of mineral from the formed working site with maintaining the stability of the redeemable side, the formation of the working platform is carried out before the redeeming of the ledge, with the output of the mineral to its slope, and the extraction of the mineral is carried out by forming deep mining cameras complex deep development of the reservoir with a multi-link conveyor. The stability of the redeemable side of the quarry can be maintained by leaving the inter-chamber pillars or by laying the worked out space of the extraction chambers by overburden.

The disadvantage of this method is that it excludes the possibility of coal mining outside the recoverable area in the fall due to the limited length of the conveyor complex, as well as the loss of minerals in the pillars between the chambers.

The closest in technical essence is the method of developing shallow seams of coal deposits (see RU No. 2312218, class E21C 41/00, publ. 10.12.2007), which includes open-cast mining, drilling of a seam with a deep seam mining complex and underground mining . After stopping the open mining operations and simultaneously with drilling the formation from the stopped open mining operations, open underground mine workings are conducted to the underground section of the formation located below the section designated for drilling the formation. A barrier pillar is left between these areas, then preparatory and rifting workings are carried out for underground excavation of the formation, and mining operations are carried out after drilling the formation from the surface or simultaneously with drilling.

The disadvantages of the known technical solutions are:

- increased coal losses in the bowels due to the need to leave pillars between adjacent chambers of the deep seam mining complex, coal losses in barrier pillars and pillars of the underground mining system;

- increase in the cost of mining due to increased labor intensity and reduced productivity in the transition to underground mining;

- the impossibility of applying the method in the development of deposits with low-power and thin layers of minerals.

The objective of the present invention is to increase the efficiency of mining a shallow seam of a mineral by open-underground mining by expanding the boundaries of the mine field, developed by the technology of deep development of the reservoir, and increasing the completeness of the extraction of reserves by excavating pillars.

To solve this problem, the method of open-underground mining of shallow seams, including preparing the site for treatment works, installing a mining complex on the site, extracting minerals with treatment chambers by conducting parallel workings, sinking the underground excavation through the formation, preparing the site for treatment works, is carried out by cutting a trench across the strike of the formation. At a distance from the trench not more than the depth of the excavation of the complex, underground excavation is carried out along the dip of the formation. Mineral extraction from treatment chambers is carried out along the strike of the formation to the intersection with the underground mine. After working, the treatment chambers are filled with a hardening solution. Between the treatment chambers leave pillars with a width of at least the width of the working body of the mining complex. After solidification of the filling mortar, the pillars are excavated. Filling the treatment chambers can be done by pouring a hardening solution with preliminary construction of insulating jumpers in the mouth parts of the chambers. As a hardening solution, you can use water or an aqueous mixture with a filler, and then it is frozen by ventilating the chamber with cold air through an underground mine. Freezing is carried out in layers by gradually increasing the height of the insulating jumpers. As a filler, a clay-clay, sludge and / or sand fraction can be used.

A comparative analysis of the features of the claimed solution with the signs of analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The features of the characterizing part of the claims provide the solution to the following functional tasks.

The sign “preparation of the site for cleaning works is carried out by digging a threaded trench across the strike of the formation” allows you to significantly expand the area of the mine field in depth along the dip of the formation and removes the limitation of the use of hydraulic fracturing only from the side of the slope of the cut by the size of the maximum conveyor length. Both a rifled trench and an underground mine can be used to extract minerals from production blocks on either side of themselves and, thus, significantly reducing unit costs for mining and preparatory work.

The sign “extraction of minerals from the treatment chambers is carried out along the strike of the formation” determines their horizontal location in space, which allows filling the chambers with a bookmark along the entire length of the excavation by spreading the solution or mixture, as a result of which the delivery of filling material is significantly simplified and labor productivity is increased. At the same time, the use of local materials and industrial wastes mixed with water and their subsequent freezing in conditions of natural cold, for example, by airing in the winter, significantly reduces the cost of filling material.

Conducting underground excavation in the formation at a distance accessible to the complex from the cutting trench allows you to accurately establish the position of the formation at the far end of the chamber and to eliminate losses and dilution of the mineral. Unlike a coal seam, this is especially important for alluvial deposits of diamonds and gold, the productive seams of which have visually difficult to define contours. Directly from underground excavation, the location of the reservoir in the enclosing massif can be determined visually or by testing using known methods, and this is an additional advantage in localizing and outlining the reservoir in situ. Also, the underground mine provides access to the treatment chamber from the other end due to malfunction, which allows greater opportunities for the delivery of filling material and ventilation of the chamber. In addition, this underground mine carries the functions of a rifled mine when it establishes the boundaries of a mining block, and / or a mining and preparatory mine if it delineates the boundaries of the mine field.

At the same time, the safe extraction of pillars contributes to an increase in the completeness of extraction of mineral reserves using deep formation mining technology and to increase the overall efficiency of mining a shallow-lying formation by expanding the limiting boundaries of the mine field.

The method is as follows.

When preparing the site for the start of treatment works, a threaded trench is drilled across the strike of the formation. In coal deposits, as a rule, this is the place where the formation exits on the day surface or the slope surface of the ledge of the coal mine. For alluvial deposits, this is the face of the opening mine - the capital trench. After preparation of the required area at the soil level of the developed formation, in parallel with the excavation of the rifled trench, installation work is being carried out to assemble the deep development complex (FGR). Simultaneously with the sinking of the cutting trench or ahead, at a distance from the trench no more than the depth of the excavation of the complex, the underground mine is drilled through the reservoir. This distance value depends on the brand of the complex and is proportional to the length of the box-shaped multi-link conveyor of the mining complex. The extraction of minerals is carried out by conducting parallel workings, chambers, along the strike of the formation with leaving pillars between them to ensure the safety of work on rock pressure. The extraction of minerals and mining the chamber is carried out before the intersection (failure) of the chamber with underground mining. The whole between the treatment chambers leave a width of not less than the width of the working body of the mining complex with the expectation of their subsequent repayment. The cameras are filled with dry or hardening filling material by known methods. After reaching the required load-bearing capacity of the hardening material, a mineral is extracted from the pillars by a mining fracturing complex.

Holding treatment chambers along the strike of the formation determines their horizontal location in space. This greatly facilitates the complexity and increases the manufacturability of operations for laying the worked out space with filling material. To do this, insulate bridges of local material (or known special insulating structures) are erected in the mouth parts of the chambers on both sides and the chambers are filled with a fluid-viscous hardening mortar based on cement or another binder component. To save the binder material, the chambers can be preloaded with filler from local materials such as a small fraction of pebble material, medium or large gal, strong overburden of the required granular composition.

In the conditions of the North and in the areas of permafrost, it is possible to significantly reduce the cost of filling material and the complexity of filling operations by using the method of ice-laying. At the same time, water or an aqueous mixture with a filler, which fills the treatment chamber between the jumpers, can be used as an astringent solution. Then this bookmark is frozen by airing the chamber with cold air through an underground mine to gain the necessary strength. To increase the efficiency of the freezing process, work on the freezing of an ice-breed bookmark is carried out in the winter.

Layer-by-layer freezing by gradually increasing the height of the insulating jumpers and airing speeds up the process of erecting the bookmark. As the filler of the mixture can be used clay-clay, sludge and / or sand fraction from the tailings.

Using the proposed method will expand the mineral resource base due to the reassessment of the conditions and the involvement in the operation of previously substandard or off-balance mineral reserves represented by low-power and thin productive strata of the mineral. For example, placers of diamonds or gold with a relatively high content in thin productive formations are not mined by the open pit due to the large value of the stripping ratio, which determines the unprofitability of the project. An alternative to underground mining of the placer is impossible due to the lack of appropriate technology and techniques for excavating permafrost sand from thin productive strata.

The set of proposed in the technical solution of the essential features of the method in collaboration with open-underground mining:

- increases the safety of mining operations and the maximum completeness of the extraction of minerals through the laying of the developed space and the redemption of the pillars of minerals;

- reduces the cost of mining due to the exclusion of overburden work on the developed layer to a significant depth by the fall of the mineral layer.

Claims (6)

1. The method of open-underground mining of shallow seams, including preparing the site for treatment, installing a mining complex on the site, extracting minerals with treatment chambers by conducting parallel workings, leaving pillars between the chambers, driving underground workings through the formation, characterized in that the site is prepared for cleansing work, they make a cut of a trench across the strike of the formation, underground excavation is carried out by the fall of the formation at a distance from the trench not more than the depth of the excavation the ki of the complex, the extraction of minerals from the treatment chambers is carried out along the strike of the formation to the intersection of the chamber with the underground mine. 2. The method according to p. 1, characterized in that the pillar width is set not less than the width of the working body of the extraction complex, after which the treatment chambers are laid with a hardening solution, and after solidification of the filling solution, the pillars are excavated. 3. The method according to p. 2, characterized in that insulating bridges are erected in the mouth parts of the chambers, and the treatment chambers are laid by pouring a hardening solution. 4. The method according to p. 3, characterized in that as the hardening solution using water or an aqueous mixture with a filler, and then it is frozen by airing the chamber with cold air. 5. The method according to p. 4, characterized in that the freezing is carried out layer by layer by phasing the height of the insulating jumpers. 6. The method according to p. 4, characterized in that the ventilation of the treatment chambers with the laying of cold air is carried out through an underground mine.