RU2341434C1 - Feeder for ore chute - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: feeder for ore chute includes ferroconcrete frames 1 with hydraulic cylinders, compass roof 2 and operating element 3 with shape of arch of interior working part of compass roof 2 corresponds to shape of arch of emptying opening 5, while interior working part of compass roof 2 of operating element 3 are made with height calculated from expression: H_cr = H_co/K_cr [1- sin (arctg h/α^1/2)], chord of compass roof 2 has width calculated from expression α = α - 2·L₃·K_k·tg45°-p/2. The operating element 3 is equipped with extended platform 4 of width equal to the width of the operating element 3 and of length equal to the length of ferroconcrete frame 1 without the compass roof of the feeder 2.

EFFECT: increased efficiency of development of mineral deposits, reduced losses dilution.

2 dwg

Description

The invention relates to mining and can be used in underground mining of inclined deposits of medium power.

A device for the production of ore located in the delivery mine is known, including a support frame on which a vibrating drive from the vibrodrive is fixed by means of shock absorbers, while the support frame is connected to a hydraulic cylinder, the rod of which is fixed to the shutter with a blind end wall (see A.S. USSR No. 1694929, IPC ⁸ E21F 13/00, publ. 30.11.91, bull. No. 44).

The disadvantages of this device are the complexity of manufacture and operation (two drives, shaped parts and assemblies, rollers, etc., made of metal based on the maximum possible load from the influence of the ore mass on the feeder parts), the possibility of jamming the feeder in bulk ore, and the most important thing is the complexity of the feeder installation in the outlet working out of the bottom of the block, since mines, unlike mines, are not suitable for moving along the workings of heavy and bulky loads, especially when installed inside the treatment block.

The closest in technical essence and the achieved result is a device for the production of ore, including reinforced concrete frames with hydraulic cylinders, arched ceilings and a working body (see AS USSR No. 1559160, IPC ⁸ E21s 41/22, publ. 23.04.90, )

The disadvantages of the prototype is that the reinforced concrete frame, floor and working body are made based on the maximum possible load from the influence of ore mass on the feeder parts without taking into account specific mining operating conditions. This, on the one hand, increases the cost of the structure, and on the other hand, does not take into account the size of the output, which leads to an increase in losses or dilution of the produced ore.

The objective of the proposed technical solution is to increase the efficiency of mining mineral deposits development systems with the release of ore under collapsed overlying rocks, reducing losses and dilution.

The solution to the technical problem is achieved by the fact that in the known feeder for the production of ore, including reinforced concrete frames with hydraulic cylinders, an arched ceiling and a working body, according to the invention, the shape of the arch of the inner working part of the arched ceiling corresponds to the shape of the arch of the exhaust working, while the inner working part of the arched ceiling of the working body made with a height equal to:

where N _in - the height of the output, m,

To _n = 2-2.5 is an empirical coefficient depending on the physicomechanical properties of loosened ore,

h - the height of the vertical part of the exhaust output, m,

and the span of the arched ceiling is made with a width equal to:

a = a′-2 · L _s · K _to · tg45 ° -p / 2, m,

where a ′ is the width of the output, m,

L ₃ - the burial of the device into the bulk of the collapsed ore, m,

To _k = 1-1,2 - empirical coefficient, depending on the size of the loosened ore,

p is the angle of internal friction of the loosened ore, and the working body is equipped with a sliding platform having a width equal to the width of the working body and a length equal to the length of the reinforced concrete frame without arched overlapping of the feeder.

This design will improve the efficiency of mining mineral deposits, reduce losses and dilution.

The invention is illustrated by drawings, where in Fig.1 is a feeder located in the exhaust output (longitudinal section); figure 2 is a transverse section of the feeder.

, выпускной выработки 5, высота свода f арочного перекрытия 2, полупролет

арочного перекрытия 2, высота h_Б вертикальных боковых стоек арочного перекрытия 2, высота вертикальной части выработки h.The ore feeder consists of a reinforced concrete frame 1 with an arched ceiling 2, a reciprocating working element 3 and a sliding platform 4 installed in the outlet 5, filled with broken ore 6 and the rock of the worked-out layer 7. Height of the outlet excavation N _in , feeder height N _p , the height of the active cross section of the outlet N _s , the depth of the feeder into the pile of collapsed ore L _s , the direction of motion and the force vector F, the height of the living section of the window AB, the height of the arch f 'of the output 5, half-span

, exhaust output 5, arch height f of arch overlap 2, half-span

arched floor 2, height h _{B of the} vertical side pillars of the arched floor 2, the height of the vertical part of the excavation h.

The feeder operates as follows.

Ore feeder is made directly in the final mine 5 when mining reserves by mining systems with face ore output.

After sinking the bottom of the block in the exhaust mine 5 produce the manufacture of load-bearing structures of the feeder for the release of ore.

In the outlet 5, temporary formwork of the reinforced concrete frame 1 is made, reinforcement is installed in it, the formwork is filled with concrete (or another hardening mixture), and a channel for placing hydraulic cylinders is formed (not shown in Figs. 1, 2). On the frame 1 install a metal formwork of the working body 3 and fill it with a hardening mixture. Hydraulic cylinders are laid in the channel of the frame 1, the rods of which are connected to the working body 3 and the frame 1. The working body 3 is equipped with a sliding platform 4 having a width equal to the width of the working body 3 and a length equal to the length of the reinforced concrete frame 1 without arched overlap 2. The sliding platform 4 overlaps the working part of the reinforced concrete frame 1, preventing the release of the produced rocks in the channel for placing hydraulic cylinders and on the frame 1. Then, the metal formwork is installed and the arch mixture 2 is filled with a hardening mixture, the height of the vertical part is rabotki h.

Places in contact with the working body 3, perform reinforced metal.

In the process, the working body 3 of the feeder makes a reciprocating motion. When you exit from under the arched ceiling 2, the working body 3 delivers the beaten ore to the transport device in the direction of motion of the force vector F (see figure 1).

The feeder for the release of ore is a feeder of active action, the element of which is the arched ceiling 2 of the movable part of the working body 3, and the arched form of the ceiling 2 is most suitable for technological reasons.

In the process, the working body 3 of the feeder makes a reciprocating motion. When you exit from under the arched ceiling 2, the working body 3 delivers the beaten ore to the transport device.

To improve performance, the feeder is equipped with a retractable platform 4, on which the ore being extracted is advanced from a common pile.

In a loose body, a stress state is called a passive resistance (according to the theory of soil mechanics).

The quantity of penetration L _of the feeder pile of broken ore at 6 was determined as the distance from the end face plane to the point of penetration of the working body 3 and calculated using the formula:

(1)

(one)

, ρ - угол внутреннего трения разрыхленной руды.Where

, ρ is the angle of internal friction of loose ore.

The height of the living section of the window AB was:

From the point of view of production technology, the above design parameters of the bottom of the treatment unit using a feeder are optimal. With a greater depth of the feeder, the resistance of the soil to the movement of the working body 3 increases, which leads to a disruption in the process of forming the outlet window AB. The decrease of penetration _of L reduces the height of the living section AB outlet.

To comply with the above conditions, it is necessary to match the arch of the arch overlap 2 of the feeder and the arch of the outlet 5 to fulfill the ratio:

where f 'is the height of the vault of the borehole supply, m,

- полупролет буродоставочной выработки, м,

- half-span of drilling deliveries, m,

f is the height of the arch of the arch ceiling 2, m,

- полупролет арочного перекрытия 2, м.

- half-span of arched ceiling 2, m.

The height of the arch of mine workings was determined by the physicomechanical properties of the enclosing rocks, and the height of the arch of arch overlap was determined by the characteristics of the massif of the excavation site, which were changed within the limits of one excavation unit.

The advantage of this feeder is its creation directly in the face in accordance with specific mining and technical conditions that determine the shape and size of the output.

In general, the arched ceiling 2 consists of vertical side racks with a height of, for example, h _B and an arched part with a height of the arch, for example, f. The height of the highest working part of the arched ceiling 2, from which the height of the living section of the outlet window AB is formed (due to equality of the height of the working body 2) is equal to H _P.

When the height of the vertical part of the excavation h, the height of the side pillar of the arched ceiling 2 h _B is determined as follows:

(2)

(2)

and the height of the arch of the arched part of the ceiling 5 according to the formula:

Based on the experimental data, the height of the working body (the height of the working part of the arched ceiling 2) is

where K _p = 2-2.5 is an empirical coefficient depending on the physicomechanical properties of loosened ore, m

At a lower height of the feeder (smaller than the front working plane of the working body 3) due to the flexibility of the ore mass, the working body 3 deforms the loosened ore mass when it leaves the arched ceiling 2, and does not move it through the outlet window AB. A large height of the feeder will lead to a decrease in the active part of the height of the outlet window AB according to dependence (1).

The width of the feeder (the value of the span of the arch ceiling 2) is equal to:

a = a′-2 · L _s · K _to · tg45 ° -p / 2,

where K _k = 1-1,2 is an empirical coefficient depending on the size of the loosened ore, m

Using the proposed feeder for ore production will allow, in comparison with the prototype, to increase the efficiency of mining mineral deposits, reduce losses and dilution, and will also allow you to create it directly in the face in accordance with specific mining conditions.

Claims (1)

Ore feeder, including reinforced concrete frames with hydraulic cylinders, an arched ceiling and a working body, characterized in that the shape of the arch of the internal part of the arched floor of the working body corresponds to the shape of the arch of the outlet, while the internal part of the arched floor of the working body (H _p ) is made in height, equal to:

where N _in - the height of the output, m; To _p = 2-2.5 is an empirical coefficient, depending on the physicomechanical properties of loosened ore; h is the height of the vertical part of the arch of the exhaust output, m; a - span of the arch overlap of the working body, which is determined by the formula: a = a′-2 · L ₃ · K _to · tg45 ° - p / 2, where a ′ is the width of the output, m; L ₃ - the burial of the device into the bulk of the collapsed ore, m; To _to = 1-1,2 - empirical coefficient, depending on the size of the loosened ore; p is the angle of internal friction of loose ore, degrees, and the working body is equipped with a sliding platform having a width equal to the width of the working body and a length equal to the length of the reinforced concrete frame without arched overlapping of the working body of the feeder.

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