SU1712672A1 - Pulp airlift - Google Patents

Abstract

The invention relates to the means of hydromechanized lifting of slurries containing inclusions of solid fractions of various density and size, and can be used in the hydrotransport of slurries to the beneficiation and processing plants of the mining and metallurgical industries. The purpose of the invention is to increase the reliability of the Pulmaa13 "and the efficiency of the airlift. A well-known installation, containing a lifting pipe 1 with a suction port 4 in the lower part, made in the form of a rectangular cutout, an air duct 3 and an air separator 2 with a reflector 10 ^ connected to the upper part of the riser, provided with an additional reflector, damping elements 11 and an additional air duct 5c a nozzle 6, the latter being located at the level of the upper edge of the rectangular notch, and the additional reflector 9 is fixed in the air vent under the main reflector 10 by means of damping .11 their elements with the possibility of vertical oscillations has M-shaped and the apertures, the diameters of which constitute the 0.05-0.10 diameter riser. 1 il.h ^ ЁyoOsVJ th —V

Description

The invention relates to hydromechanized lifting of slurries containing inclusions of solid fractions of various density and size, and can be used in the hydrotransport of slurries at the beneficiation and gold recovery plants of the mining and metallurgical industries.

Known airlift for lifting pulp containing lifting pipe, plugged from the top end, located in the housing of the air separator and having side windows for exit of the pulp. The top of the air separator is plugged at the top and provided with a throttle valve for exhausting air, the pipe for draining pulp from the air separator housing is also provided with a throttle valve. Throttling of the slurry and air outlet allows to increase the pressure in the air separator and the upper part of the riser, as a result of which the velocity of the slur at the outlet of the riser decreases as a result, the wear rate of the air separator components and components decreases.

However, in this airlift, due to an increase in pressure in the air separator, the supply of the airlift and its efficiency are reduced,

The aim of the invention is to increase the reliability and efficiency of the airlift.

The drawing shows schematically an airlift for raising the pulp, a general view.

The airlift for lifting the pulp contains a lifting pipe 1 connected in the upper part with an air separator 2, and in the lower part with an air duct 3. In the lower part of the lifting duct, a window 4 is made on the side opposite to the air duct 3. An additional air duct 5 ends with a nozzle 6. Air ducts have valves 7 and 8. The air-lift of the airlift has two successively installed reflectors 9 and 10. The lower DO complementary M-shaped reflector 9 with openings is attached to the casing of the air separator 2 through damping devices 11 a mechanical, hydraulic, pneumatic or other. type. The upper reflector 10 is rigidly fixed to the air separator body.

In the lower part of the air separator housing there is a drain nipple 12. On the inner surface of the air separator casing, two sides of the upper 13 and lower 14 are installed along its perimeter. The sump 15 has drainage grooves 16 and a grate 17,

Before launching the airlift, the pulp through the drainage grooves 16 through the grate 17 enters the sump (capacity) 15. To prevent the oversized particles of rock mass from entering the sump, the holes in the grate 17 should not exceed 0.3 diameters of the riser. During the pre-start period, the valve 7 of the air line 3 is closed, and the valve 8 of the additional air line 5 is open. Compressed air enters through the air duct 5 and the nozzle 6, the outlet of which is located flush with the upper edge of the rectangular notch 4. Such an arrangement of the nozzle with respect to the suction window allows the most fully utilized energy of the supplied compressed air. With this arrangement of the nozzle, the compressed air coming out of it forms an area of active mixing of the pulp adjacent directly to the suction window 4.

The location of the nozzle above or below the upper edge of the suction port shifts the zone of active mixing of the pulp, respectively above or below the suction port, which impairs the process of suction of solid particles and reduces the flow of airlift along the rock mass. In addition, it is precisely with this arrangement of the nozzle that the largest part of the compressed air from the injector is sucked into the lifting pipe of the lift. This part of the air in the lifting pipe does additional work on raising the pulp, which increases the flow and efficiency of the airlift.,

The air coming from the nozzle 6 ensures the mixing of the pulp in the zone of the suction port 4, which prevents solid particles from settling down, the material sucking the suction port and ensuring the reliability of the airlift start-up.

The air lift is started by opening the valve 7. Compressed air through the air duct 3 enters the lifting pipe 1 and, expanding, lifts the slurry. After the launch of the airlift into operation, the air coming from the nozzle 6 continues to mix the slurry in the suction zone, thereby providing a more active suction of solid particles, which ultimately increases the airlift supply over the rock mass.

When the airlift is operating, the three-phase medium emerging from the riser enters the air separator and hits the lower additional reflector 9 with apertures -: mi. Part of the pulp and air passes through the holes, and the other part of the pulp, hitting the lower reflector, goes through the drain pipe 12. Thanks1 to the output of the medium that came from the riser, through the holes in the lower reflector in the zone of the upper section of the riser 1 and the lower reflector 9 pressure decreases, which leads to a decrease in pressure at the outlet of the riser, as a result of which, with a constant flow of air, the airlift supply increases,

. The lift increases.

The decrease in pressure in the zone between the lower reflectors and the upper cut of the riser pipe is also facilitated by the presence of dampers 11, which provide oscillatory movements of the lower reflection bodies with a frequency corresponding to the pulsation frequency of the airlift. In the period of time when the airlift supply increases, the lower reflector moves upwards, thereby providing a reduction in the volume of this zone, as a result of which the pressure in this zone decreases.

The M-shape of the lower reflector reduces the impact of the shock pulse on its surface by replacing the direct blow with an oblique; as a result, the wear rate of the reflector decreases and the service life of the air separator increases.

Part of the pulp, passing through the holes in the lower reflector, falls into the upper solid reflector, reflected from it, the pulp falls into the lower part of the air separator to the drain pipe 12.

The application of the proposed installation improves the reliability of the airlift and its efficiency.

Claims (1)

Invention Formula Airlift for raising the pulp, containing a lifting pipe with a suction window in the lower part, made in the form of a rectangular cutout, an air line and an air separator with a reflector, connected to the upper part of the lifting pipe, so that in order to increase reliability and efficiency, the air-lift is equipped with an additional reflector, damping elements and an additional air pipe with a nozzle, the latter being located at the level of the upper edge of the rectangular notch, and an additional reflector fixed in the air vent Ithel under the main reflector by means of damping elements, with the vertical oscillations has M-shaped and of miles away, the diameter of which is 0.05-0.10 of the diameter of the riser.