SU848065A1 - Electrostatic separator - Google Patents

Description

(54) ELECTROSTATIC SEPARATOR

Claims (3)

The invention relates to the enrichment of minerals and can be used in the ore dressing industry in the separation of conductive and non-conductive particles, in the separation of plastics from metallic inclusions. The electrostatic separator is known, including a feeder, an electrode system, receivers of separation products p. The closest to the proposed technical essence and the achieved effect is an electrostatic separator including a feeder, an electrode system consisting of precipitating and deflecting electrodes, electrical separators, receivers of separation products. The disadvantage of the known separators is the low efficiency of the separation process due to because it is impossible to create a non-uniform electric field in all necessary separation zones. The purpose of the invention is to increase the efficiency of the separation process by creating an additional non-uniform electric field in the working area. This goal is achieved by the fact that the separator is provided with an additional deflecting electrode made in the form of a base with rods that are cantilever-mounted on it and thickened at the free ends, while the base is mounted so that it can move relative to the main deflecting electrodes. Moreover, the thickenings may have a spherical shape, and the base may be made in the form of a strip. In addition, in order to adjust the gradient of the electric field, the additional electrode can be equipped with a rail with holes for the rods fixed on the latter by means of a clamp. FIG. 1 and 2 schematically illustrate embodiments of the separator in FIG. 3 is a view of A in FIG. one; in fig. 4 is a view B in FIG. 2, the Separator includes a feeder 1, a creeping electrode 2 in the form of a plane intended for supplying the material to be separated into the zone of action of the deflecting electrodes 3 and 4, an additional electrode 5 made in the form of a base 6 with cantilever rods 7 sec. 8n free ends, the base can be made in the form of a strip, and the thickenings can have a spherical shape, Electrode 5 can be equipped with a rail 9 with holes for rods designed fyiH adjusting the intensity of the electric field Capacity 8, (the gradient decreases with when the rail moves closer to the thicknesses), a clamp 10 is provided for securing the rail 9 at a certain distance from the thicker -8. Electrode 5 is grounded or connected to the source depending on the type of material to be divided. current and mounted on brackets 11, mounted with the possibility of movement in the hinges 12, the separator 13 and 14 are also installed in the separator to control the output of the separation products to the receivers 15-17. The separator works as follows. The material from the feeder 1 enters the plane 2 and further into the zone of action of electrodes 3 and 4. In the electrostatic field of the electrodes, free charges are accumulated at opposite ends of the separated particles. The magnitude of the bipolar charges depends on the electrical resistance and the shape of the particles, and the rate at which these charges accumulate also depends on the dielectric constant of the particles. The magnitude of the bipolar charges of the conductive particles is several orders of magnitude higher than that of the nonconductors. In a non-uniform electric field, the particles are subject to a force proportional to the magnitude of the intensity gradient and the charge on the particles; therefore, the conductive particles are drawn into the non-uniform field. The conductive particles touch the electrode, recharge, and bounce off it. Non-conducting particles 54 electrodes that create an uneven field have less effect. When installing an additional electrode 5 in accordance with FIG. 1, behind the electrode 3, a zone of increased tension of the electrostatic field arises, facilitating the direction of the conductive particles into the receiver 17. However, some of the conductive particles do not acquire sufficient bipolar charges due to the fact that they are inside the material flow and are directed to the intermediate product receiver 16 or receiver 15 non-conductive particles. When an additional electrode 5 is installed in accordance with FIG. 2, the conductive particles do not enter the receivers 15 and 16. The non-conductive particles do not have time to recharge and enter the receiver 13. The position of the electrode 5 above the receivers 15 and 17 is determined by the requirements of recovery and recovery of separation products. When the separator is supplied with an additional electrode 5, a corona current is not created, at the occurrence of which the particles acquire free charges, and it becomes possible to adjust the gradient of the field strength at the electrode, which increases the efficiency of the separation process. 1. Electrostatic separator including a feeder, an electrode system consisting of precipitation and deflecting electrodes, cutters, receivers of separation products, characterized in that, in order to increase the efficiency of the separation process, by creating an additional non-uniform electric field in the working area, the separator is equipped with an additional deflecting electrode, made in the form of a base with rods cantileverly mounted on it with thickenings on the free ends, while the base of the mouth Antennaable for movement relative to main deflecting electrodes. 2. A separator according to claim 1, characterized in that the bulges have a spherical shape. 3. A separator according to claim 1, characterized in that the base is in the form of a strip.