RU2213867C2 - Method of mineral mining - Google Patents

Abstract

FIELD: technology of mineral mining by opencast methods or by underground mine workings of vertical, inclined or horizontal locations. SUBSTANCE: method includes driving of working in mass of mineral and installation of hollow guide support carrying rock breaking unit into said working, layer-by-layer working of face in circular and radial directions, loading and haulage of rock to receiving chamber, ore introduction into containers, moving of containers over hydraulic main line where they are given positive buoyancy, unloading of containers in atmosphere medium, returning of containers after unloading over main line in gas medium with braking of empty container by front resistance and air flowing-over from bottom upward along its walls and walls of main line. As face advances, rock breaking unit is moved along generating line of guide support to face. District of rock mass mining is selected in circular and radial directions depending on content of useful mineral in ore mass. EFFECT: higher efficiency of all operations forming process line of offered method of mineral mining. 5 dwg

Description

 The invention relates to the technology of mining, carried out by the development of rocks by open pit mining or by closed pit mining when laying a mine vertically, obliquely or at an angle to the horizontal, or horizontally.

 At present, the principal directions of solutions for the implementation of this technology are known, of which the most representative and closest, according to the applicant, is a method of mining, including opening a mineral array in geological structures, development, loading, transportation of ore into the cavity of the receiving chamber, input ore into containers and their supply through the hydraulic highway, where they set a positive buoyancy of the ore container and unload it in the atmosphere, return empty containers for loading (see SU 829520 A, 05.25.1981).

 Possessing certain advantages over other analogues, in particular, the efficient operation of opening the ore horizon, this method has significant and obvious drawbacks, namely, high specific labor and energy costs for the process of developing the face along its effective area, for the process of feeding ore to the conveyor line, returning empty containers. The lack of continuity and continuity boils down to the need for joining the individual operations and processes of the method to complete its production line, which leads to the cost of additional labor and time, reflected in a decrease in the efficiency of the whole method.

 The technical task of the invention and its technical result is to increase the efficiency of all operations that make up the technological line of the method with obtaining a single continuous process from opening the rock mass to returning containers for loading, which makes the method mobile and autonomous.

 The problem is achieved due to the fact that the method includes opening an array of minerals in geological structures, developing, loading, transporting ore into the cavity of the receiving chamber, introducing ore into containers and feeding them through the hydraulic line, where they set positive buoyancy for the ore container and unload it in the atmosphere, return empty containers for loading. In accordance with the invention, a mining is carried out in a mineral array, a hollow guide-support in the form of an elongated hollow cylinder is immersed in this mine, a rock-breaking assembly is mounted on this support, which can rotate around the guide-support using a movable band, this unit conducts layer-by-layer mining of the face in the circular and radial directions, and after unloading the containers, they are returned along the highway in a gas medium, braking the empty container due to drag and air flowing from bottom to top along its walls and the walls of the highway, and as the face is developed, the rock cutting unit is moved along the generatrix of the support guide to the bottom, while the choice of the site for developing the massif is carried out in circular and radial directions depending on the mineral content in the ore mass.

The method of mining is illustrated by drawings,
where in FIG. 1 shows a General view of the technological scheme of the method;
in FIG. 2 - a general view of technical equipment and the process of ore development in vertical section;
in FIG. 3 is a plan view of the technical complex of the method;
in FIG. 4 is a top view (in plan) of a scraper plate conveyor;
figure 5 is a side view of the conveyor (in profile).

 The technical equipment in its complex, as shown in the aforementioned drawings, includes a hollow guide rail-support 1, which is an elongated hollow cylinder, which is immersed in the drilled hole 2, also includes a rock cutting unit 3 containing a combined working body of working nozzles and mechanical cutters ( not shown) also contains a scraper plate conveyor 4 for sampling the destroyed rock (ore). A scraper plate conveyor 4 (Fig. 3, 4, 5) for collecting the destroyed rock (ore) is connected functionally with the receiving chamber 5, located in the cavity of the support 1.

In the receiving chamber placed containers 6, loaded with the developed rock (ore). The transportation of these containers is carried out in the cavity of the hydraulic line 7 before rising to the curved section 8, which then continues in one of three laying options: if the highway 9 is laid horizontally or at an insignificant angle to the horizontal (no more than 1 ^o ), then this highway can be filled with a working a liquid, and containers 6 are transported through its cavity using their positive buoyancy and when purging along the containers; if the highway 9 is laid with a slope (down), the movement of the containers is carried out by lowering and braking; If line 9 is laid elevation (upward), its cavity is filled, as the initial portion of the cavity gidromagistrali 7, the working fluid and the container is fed due to its positive buoyancy, and at a small angle of rise ^(to + 5) fed with blowing during the movement of the container . To do this, use a pneumatic pressure unit 10, and the supply pipes 11 are inserted along the bevel in the direction of movement of the container along the highway 9.

 The highway 9 is connected to the receiving platform 12, where the containers are unloaded in the atmosphere. After unloading, the containers 13 (empty) are fed through the cavity of the return line 14, the laying of which in the profile can also be in different versions: horizontally, obliquely, with a lift, as the line 9. In addition, the same section as the section of the line 9 , and the section of the highway 14, can be laid both in plan and in the profile at different angles and in such different sections can be filled in their cavities with both working fluid and air (combined filling of the cavity). Guide-support 1 has a movable bandage 15, placed on its generatrix, for example, using rollers. With the help of these movable bandages 15, the receiving chamber 5 has the ability to freely descend as the pit 16 deepens when excavating at its bottom-face.

 The scraper plate conveyor 4 is mounted on the guide rail 1 using a movable band 15, which allows the conveyor 4 to move in two directions: relative to the axis of the guide rail 1 and relative to its generatrix - rotation around the support (moment "M"). The conveyor 4 has drive drums 17 and 18, between which, and running around them, the plate conveyor 19 is pulled from individual plates interconnected by hinges. Cutters 20 are fixed on the plates (Fig. 4, 5) with a bevel in plan so that when developing ore at the bottom of the pit 16, the ore moves to the center of the pit and enters the receiving chamber 5 of the guide-support 1, where the ore is loaded into containers.

 The described method is carried out by preliminary formation of the mine 2, the guide-bearing 1 is immersed in its cavity and the receiving chamber 5 and the rock cutting unit 3 are mounted on its outer side with the help of a movable band 15, and the conveyor 4 is mounted with their standard power drives (drive details in the drawing not shown). All highways are turned on and checked: 7, 14, 8, 9. Using a rock cutting unit 3, the rock is developed with a given destruction layer, and this destroyed rock layer is selected by conveyor 4 and fed to the receiving chamber 5 for loading containers 6.

 Containers 6 are loaded based on their preservation of positive buoyancy in the working fluid medium, into which they are introduced by feeding into the cavity of the hydraulic highway 7, where the containers float, pass through section 8 and enter the highway 9, the supply of which, as described above, can be carried out by one of three options: due to the same positive buoyancy, due to buoyancy with additional supply of pressure air in the direction of movement of the container, due to only supplied pressure air in the direction to the platform 12 for receiving and unloading the container When the empty containers are delivered via line 14. In this case, one of the three indicated options (or combined combined at sections of the line) of container supply 13 is also used: in the working fluid medium, or in the air medium, or in the liquid medium with air purging along the way container. And the descent of containers on the vertical section of the highway 14 is most efficiently carried out in air during pneumatic braking of containers in this limited section of the highway due to the developed drag in the midship area of the container and the gradual flow of air from bottom to top along its walls and walls of the highway 14 in this section of the descent of containers under loading.

 Thus, the developed method of mining has a universal and original technological scheme for the implementation of all its sequentially performed operations, which allows you to organize a closed circuit from development to the supply of developed ore for processing, to make the process completely autonomous if it can be automated (with unmanned technology), which especially important when developing quarries in regions remote from human settlements.

 In the implementation of this method, it is possible to annularly develop a face (bottom of a pit 16) with the formation of a uniformly radial excavation of the pit, as well as possible selective destruction and selective sampling of the rock in the presence of richer ore in local areas, which may be carried out with a mobile scheme of the rock cutting unit (it sliding and shortening) and with the same mobile design of the ore-picking conveyor.

Claims (1)

 A method for extracting minerals, including opening an array of minerals in geological structures, developing, loading, transporting ore into the cavity of the receiving chamber, introducing ore into containers and supplying them via a hydraulic highway, where they set positive buoyancy for the ore container and unload it in the atmosphere, empty containers are returned for loading, characterized in that the mine passes through a mine, the hollow guide-support in the form of an elongated floor is immersed in this mine of the second cylinder, a rock cutting unit is mounted on this support, which can be rotated around the guide support using a movable bandage, this unit conducts layer-by-layer mining of the face in the annular and radial direction, and after unloading the containers, they are returned along the highway in the gas medium, braking the empty container due to drag and air flow from bottom to top along its walls and the walls of the highway, and as the face is developed, the rock cutting unit is moved along the generatrix on the governing support to the face, while the choice of the site of development of the massif is carried out in circular and radial directions, depending on the content of the mineral in the ore mass.

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