RU2608120C2 - Flotation classifier - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to concentration of ores by flotation. Flotation classifier comprises a cylindrical chamber with a lower conical part connected with a sands unloader, an installed inside the chamber coaxially with it open from above cylindrical collector of fine particles drain with an inclined drain branch pipe and a pulp level regulator, aerators installed between the chamber walls and the cylindrical collector of fine particles drain, a lower product collector, installed in the upper part of the chamber narrowing chutes made with a lower narrow portion of the bottom and with lower product flow rate regulators and connected in the lower narrow part of the bottom with the lower product collector by means of branch pipes, an installed inside the chamber foam-collecting chute for the upper product of the narrowing chutes and a tangential branch pipe to feed the initial pulp installed to provide a rotational movement of the pulp in the chamber. Narrowing chutes are installed in the upper part inside the cylindrical chamber perpendicular to its radius and are provided with boards having a horizontal upper edge and cutouts for outlet of the upper product of the narrowing chutes in the lower narrow part of the narrowing chutes. Foam-collecting chute for the upper product is located under the narrowing chutes and is made with an output from the chamber.

EFFECT: provided is higher efficiency of flotation classification.

1 cl, 3 dwg

Description

The invention relates to mineral processing by flotation and can be used in non-ferrous and ferrous metallurgy during flotation processing of ores.

A flotation classifier is known, including a cylindrical conical chamber with a sand unloader located at the bottom, a cylindrical conical flow distributor with a drain inclined nozzle installed coaxially to the chamber, aerators installed in the space between the chamber walls and the distributor of flows, an annular foam trough located on the outside of the chamber [1].

The closest to the proposed technical essence and the achieved result is a flotation classifier, including a cylindrical conical chamber with a sand unloader located in the lower part, a cylindrical conical flow distributor with an inclined drain pipe installed coaxially with it, installed in the space between the chamber walls and the aerator flow distributor, tapering troughs installed in the upper part of the chamber with flanges of constant height with vertical nozzles in the lower narrow the lower part of the bottom, the flow regulators of the lower product installed above the vertical nozzles in the tapering grooves, the foam collecting chute for the upper product [2].

A common drawback of the known flotation classifiers is the low efficiency of the flotation classification process, due to the uneven flow in the chamber, which leads to the removal of small particles into the sands, and large particles to the drain, the short contact time of the floated particles with air bubbles and the large transfer of non-floated particles to the foam product.

The technical result of the invention is to increase the efficiency of flotation classification due to the rotational movement of the pulp and foam, by reducing the unevenness of flows, by increasing the likelihood of contacts of floated particles with air bubbles and fixing them at the liquid-gas interface, by intensifying the processes of secondary concentration of minerals in foam on the surface of a rotating pulp and in tapering gutters.

The specified technical result is achieved in that the flotation classifier, including a cylindrical conical chamber with a sand unloader located at the bottom, installed inside the chamber coaxially with the cylindrical discharge collector open at the top with an inclined drain pipe and a slurry level regulator, installed in the space between the chamber walls and the cylindrical collector draining aerators installed in the upper part of the chamber; narrowing troughs with nozzles connected to the lower product collector in the lower narrow parts of the bottom, equipped with flow regulators of the lower product, a foam collecting chute installed inside the chamber for the upper product of the tapering chutes, is equipped with a tangential nozzle installed outside the chamber for supplying initial power, the tapering chutes inside the cylinder-conical chamber are installed perpendicular to the radius of the chamber, the sides of the narrowing chutes are made with a horizontal upper edge, and in the lower narrow part of the tapering troughs in the sides are cutouts for the release of the upper product. In this case, the foam collecting chute for the top product is located under the tapering chutes with the exit of the flotation classifier chamber.

In FIG. 1 is a top view of a flotation classifier; in FIG. 2 - section aa; in FIG. 3 - section BB.

The flotation classifier includes a cylinder-conical chamber 1 with a sand unloader 2 located in the lower part, installed inside the chamber 1, a cylindrical drain collector 3 coaxially open from above, with an inclined drain pipe 4 and a level regulator 5, installed in the space between the walls of the chamber 1 and the cylindrical drain collector 3 aerators 6 installed in the upper part of the chamber 1 perpendicular to its radius tapering grooves 7, the sides of which are made with a horizontal upper edge and cutouts in the lower narrow part for the release of the upper product, with nozzles 8 located in the lower narrow part of the bottom of the tapering grooves 7, connected to the collector of the lower product 9, flow regulators 10 of the lower product of the tapering grooves 7 installed above the nozzles 8, installed under the tapering grooves 7 with a foam collecting trough outside the chamber 1 11 for the top product of the tapering troughs 7, a tangential pipe 12 mounted outside the chamber 1 for supplying initial power to the flotation classifier.

Flotation classifier works as follows.

The pulp is fed into the cylindrical part of the cylinder-conical chamber 1 tangentially through the tangential pipe 12, acquires a rotational movement in the chamber 1. Large particles of the initial product (sands) are moved to the walls of the chamber 1 due to centrifugal force and are lowered in a spiral into the lower conical part and unloaded using the unloader sand 2.

Small particles (discharge) by gravity are sent to a cylindrical discharge collector 3, where due to ascending flows they rise up and discharge through an inclined drain pipe 4. The pulp level in the chamber 1 is regulated using the level regulator 5. When air is supplied to the aerators 6 in the space between the walls chamber 1 and a cylindrical discharge collector 3, an upward flow of air bubbles is formed, which forms a mineralized foam on the surface of the pulp, which acquires a rotational movement on the surface of the rotating pulp and flows by gravity into the tapering troughs 7.

The foam product in the tapering troughs 7 undergoes a process of secondary concentration of minerals during narrowing of the flows. As the narrowing of the foam product increases in height, and the top product flows by gravity through the cutouts in the sides of the tapering grooves 7 into the foam collection chute 11, which is discharged from the classifier. The lower product of the tapering grooves 7 is removed from the classifier through the nozzles 8 and the lower product collector 9. The desired flow rate of the lower product of the tapering grooves 7 is set using flow regulators 10.

The presence in the flotation classifier of the tangential pipe 12 mounted outside the chamber 1, installed perpendicular to the radius of the chamber 1 of the tapering grooves 7, the sides of which are made with a horizontal upper edge and cutouts for the release of the upper product in the lower narrow part, installed under the tapering grooves of the foam collection trough 11 for the upper product with the exit of the chamber 1 thereby provides high efficiency processes flotation. Ensuring the rotational movement of the pulp in the space between the walls of the chamber 1 and the cylindrical drain collector 3 provides, due to the action of centrifugal force, the effective removal of large particles (sand) from the pulp to the periphery of the chamber 1 and then to the lower conical part to the sand unloader 2. Rotation of the pulp with air bubbles provides an increase in the efficiency of hydraulic classification by reducing uneven flows and reduces the loss of small particles in the sands and large particles in the discharge, provides increasing the flotation efficiency of hydrophobic particles by increasing the probability of their contact with air bubbles and fixing at the liquid-gas interface.

The rotational movement of the foam product leads to a high degree of secondary concentration of minerals in the foam before it enters the narrowing troughs by increasing the residence time of the foam on the pulp surface.

The installation perpendicular to the radius of the chamber 1 tapering grooves 7, the sides of which are made with a horizontal top edge and cutouts for the release of the upper product in the lower narrow part, and the installation under the tapering grooves 7 of the foam trough 11 with the exit to the outside of the chamber 1 provides high efficiency enrichment of the foam product in the tapering gutters 7 due to the intensification of the processes of the secondary concentration of minerals by narrowing the flows of the foam product, effectively removing the upper product through cutouts in the sides of the tapering of the foreheads and along the foam collecting chute 11 open at the top.

The optimal modes of flotation classification are ensured by adjusting the flow rate of the lower product of the tapering troughs 7 by flow controllers 10, by changing the initial feed rate, by adjusting the pulp level in the chamber 1 using the level 5 regulator, by changing the narrowing angle between the sides of the tapering troughs 7.

Thus, the proposed flotation classifier increases the efficiency of the flotation classification process due to the rotational movement of the pulp and foam, by reducing the unevenness of flows, by increasing the likelihood of contacts of flotated particles with air bubbles and fixing them at the liquid-gas interface, by intensifying secondary processes the concentration of minerals in the foam on the surface of a rotating pulp and in tapering gutters.

Sources of information taken into account

1. USSR Copyright Certificate No. 984497, cl. B03D 1/14, 1982.

2. RF patent No. 2548866, cl. C22B 3/02, B03D 1/14, 2014.

Claims (1)

A flotation classifier for ore dressing, containing a cylindrical chamber with a lower conical part connected to a sand unloader, installed inside the chamber coaxially with the cylindrical collector for discharging small particles with an inclined drain pipe and a slurry level regulator, aerators installed between the chamber walls and the cylindrical collector discharge of small particles, a collector of the lower product, tapering troughs installed in the upper part of the chamber, made with the lower narrow part of the bottom and races regulators the course of the lower product and connected in the lower narrow part of the bottom to the collector of the lower product by means of nozzles, and a foam collecting chute installed inside the chamber for the upper product of the tapering chutes, characterized in that it contains a tangential nozzle for supplying the initial pulp, installed to ensure rotational movement of the pulp in the chamber while tapering troughs are installed in the upper part inside the cylindrical chamber perpendicular to its radius and are made with sides having a horizontal upper edge and in cuts for discharging the overflow troughs tapering in the lower narrow part of the tapered troughs, wherein penosborny chute located below the overflow gutters tapered and is configured with the output from the camera.

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