SU904788A1 - Flotation machine cone impeller - Google Patents

Description

The invention relates to mining engineering and is intended for the aeration of pulps during the flotation of ores of minerals, and can also be used in industries where aeration of liquid media is necessary.

A finger impeller is known, which is a carrier disc and fingers located vertically down on its periphery. In the center of the carrier disc there are holes for the passage of air through the hollow shaft into the sub-impeller space.

However, this finger impeller during operation does not provide sufficient aeration of the pulp in the flotation chamber, as a result of which the flotation itself does not go through the entire volume of the flotation chamber, but only in a much smaller part of it.

Closest to the proposed invention in its technical essence and the effect achieved is a conical impeller of a flotation machine, including a carrier disk with dispersing elements. The conical shape of the impeller contributes to a good dispersion of air and pulp aeration throughout the chamber volume due to different linear velocities.

separation of particles from the impeller and, provides a good intra-chamber circulation of the pulp 2,

However, in the flotation of mineral ores with a high specific gravity, the known impeller does not ensure the achievement of high performance. In addition to this, the cavity of the impeller shaft is overgrown with sediments and clogged with sands, penetrating into the shaft cavity through an opening in the impeller disk, which greatly reduces pulp aeration.

The aim of the invention is to increase the recovery of the valuable component.

The goal is achieved. By the fact that the impeller is provided with a check valve, air holes are made in the carrier disk above the dispersing elements, and the dispersing elements are made in the form of grooves with a V-shaped profile, the width of their sides increasing along the height of the impeller.

FIG. 1 shows an impeller in two projections; in fig. 2 - displacement of air and pulp flows during the impeller operation.

The impeller consists of a horizontal carrier disc 1

with dispersing elements 2, made in the form of grooves with a V-shaped profile and adjacent one end to the collar 3. The walls of the grooves are made oblique, while their width increases along the height of the impeller. Holes 4 are placed above the blade grooves in the carrier disk. All the blade matings with the disk are fillet of large radius. In the center of the carrier disc. There are a hole 5 for supplying air and a recess b on the flat surface of the carrier disc to couple the impeller to the flange of the hollow shaft of the flotation block. Hole 5 is blocked by a slotted check valve 7. At the periphery of the undercut in the bearing disc there are holes 8 for attaching the impeller to the flange of the flotation block shaft.

The impeller is non-metallic, whole-cast, molded or extruded, for example, from rubber or caprolon. The construction is performed without a skeleton. With this production, the design of the impeller is resilient and elastic, has sufficient strength and manufacturability.

The impeller may also be made of metal, for example, a welded steel structure, but this will increase the labor intensity of manufacture.

 Impeller works as follows.

When the impeller rotates, the compressed air is supplied through the hollow shaft 9. In the sub-impeller space, through a non-return valve embedded in the carrier disk 1, it is evenly distributed into the pulp through the gaps 10 formed by the walls of the grooves. The pulp is captured by the -dispersing elements 2, mixed with air coming from the sub-impeller space through the gaps 10 at the moment of its separation from the walls of the blades and thrown together with air tangentially into the cavity of the chamber. Due to the uniform alternation of the pulp and air, due to the design of the impeller, a high dispersion of air bubbles is achieved. At the moment of repulsion of the pulp by the impeller, a reduced pressure ion is created in the blade groove through the hole 5 in the disk

pulp flows under the chute, which ensures its circulation in the impeller zone.

Due to the bevel of the walls of the impeller grooves, the pulp-air particles

they have different linear speeds of detachment from the blade; accordingly, these particles are affected by various forces, increasing in direction vertically upwards.

0 The resulting force, directed from the lower edge of the blade along the curve upwards, creates intracameral circulation. The combination of intra-chamber circulation in the impeller zone

5 allows for maximum aeration, i.e. pulp saturation with air.

An annular shoulder 3 prevents the premature release of air from the sub-impeller space and ensures its penetration to a greater depth of the photocell.

At the time of the air pressure drop, the check valve 7, under the pressure of the pulp, closes its access to the cavity

5 of the hollow shaft 9. In connection with the improvement of pulp aeration and dispersion of air supplied to the chamber through the hollow shaft of the flotation block using the proposed impeller, the flotation process takes place over a considerable chamber volume, which entails an increase in the extraction of the valuable component.

Claims (2)

1. Karamzin V.I. and others. Mineral processing machinery. M., Nedra, 1974, p.258. 2. Meshkerov N.F. Flotation machines. M., Nedra, 1972, p. 108 (prototype).