SU1660751A1 - Electrostatic separator - Google Patents

Abstract

The invention relates to the enrichment of minerals using electrical separations in the separation of bulk mixtures in the mining industry, the industry of building materials, and other sectors. A housing 2 is located under the feeder 1. Inside it there are deposited electrode (E) 3 connected to the opposite poles of the high-voltage source 5 and the high-voltage E 4 coaxially located to it. The E 3 is made of circumferentially spaced and mounted rods 8. The circumference of the gap between the axes of the rods 8 is 0.12-2.1 times the radius of the circumference of the precipitating E 3. Rods 8 m. are made electrically insulated relative to the housing 2 and installed along a generatrix in the form of a truncated cone with a decrease in the interelectrode distance in the direction of movement of the separated particles. Receivers 6 and 7 of the separation products are located below the E 3 and 4. The particles from the feeder 1 fall into the working area between O 3 and 4 and move in it under the action of an electric field and gravity. The fast-burning particles are deflected along a steep trajectory and enter the receivers 6. Slowly charged particles fall into the receivers 7. 2 Cp f-crystals, 3 sludge.

Description

a bit of a cone with a decrease in the interelectrode distance in the direction of movement of the particles being separated. Receivers B and 7 of the separation products are located below Oe 3 and 4. The particles from the feeder 1 fall into the working area between O 3 and 4 and move

in it under the action of an electric field and force of tin. The fast-burning particles deflect along a steep trajectory and enter the receivers 6. Slowly charging particles enter the receivers 7. 2 Cp. f-ly, 3 silt

The invention relates to the enrichment of minerals, namely, the designs of electrical separators for the enrichment or separation of bulk materials, and can be used in the mining industry, the building materials industry and other fields.

The purpose of the invention is to increase the separation efficiency.

FIG. 1 shows a separator, a longitudinal section; in fig. 2 - the same, with converging electrodes; in fig. 3 shows section A-A in FIG. 1 and 2.

The electric separator includes a feeder 1, a housing 2 located beneath it, inside which a collecting electrode 3 and a high-voltage electrode 4 arranged coaxially to it, a high voltage source 5 are placed for connecting their opposite poles to electrodes 3 and 4. At the bottom of the separator, receivers 6 and 7 separation products for fast-acting particles (receiver 6) and for slowly charged particles (receiver 7).

The precipitating electrode 3 is made of circular rods 8, circumferentially spaced relative to each other, the gap I between the axes of the rods 8 circumferentially being 0.12-2.1 times the radius R (or RI and Ra). circumference of the precipitation electrode 3, i.e. installed from 3 to 50 rods 8. The diameters of the rods 8 and electrode 4 are significantly less than the value of R and I.

The rods 8 may be rotatably mounted around their axes using an actuator 9. To clean the rods 8 from dust stuck to them, a cleaning device 10, such as brushes, is installed at the surface of the rods 8 on the side remote from the high-voltage electrode 4.

The rods 8 can be installed along a generatrix having the shape of a truncated cone, with a decrease in the interelectrode distance in the direction of movement of the particles to be separated.

The separator works as follows.

Particles of the material to be separated from the feeder 1 are fed to the central part

precipitating electrode 3, into the working area between the high-voltage electrode 4 m by the precipitating electrode 3 connected to the source 5 Particles of the separated material, charged by a corona discharge or tribose charge, move in the working area under the influence of electric field forces and gravity.

Consider the work of the separator in the separation of mica from quartz and molybdenite from

silicates Particles of mica (or molybdenite) in the field of corona discharge are quickly charged due to their flat shape and high dielectric constant, the particles of quartz (and silicates) are slowly charged.

Under the action of an electric field and an electric wind, the rapidly mica particles of mica deviate along a steep trajectory from electrode 4 to electrode 3 and slip into the gaps I between the rods.

8 into the receiver 6. The geometry of the force lines of the electric field (the curvature of these lines) contributes to the latter, since the particles move tangentially to these lines. The distortion of the lines of force (distinguishing them from the straight lines) is due to the fact that the rods 8 are located at a distance of NI determined by the ratio of I / R 0.12

With a distance determined by the ratio I / R 2,1, i.e. If the device has less than three rods 8, the electric field near the high voltage electrode 4 is strongly distorted and even particles with the same properties acquire charges of different size.

The particles of quartz move along a gentle trajectory mainly under the force of gravity and enter the receiver 7. The particles of material adhering to the rods 8, which can rotate around their

axes using the actuator 9 are cleaned with brushes 10.

Thus, the implementation of the precipitation electrode 3 of the rods 8 provides small dimensions of the separator, the selective action of electric forces on the components to be separated, the stable intensity of the electric field in the working area.

Claims (3)

The invention is 1. An electric separator comprising a feeder, a housing located under it, inside which a precipitating electrode and a high-voltage electrode located coaxially located to it, a high voltage source for connecting their opposite poles to the electrodes and receivers of products Editor S.Pekar Compiled by V.Morozov Tehred M. Morgenthal 0 five characterized in that, in order to increase the separation efficiency, the deposition electrode is made of large cross-section rods circumferentially spaced relative to each other, the gap between the axes of the rods circumferentially being 0.12 - 2, 1 of the radius of this circle. 2. The separator according to claim 1, of which is that the rods are mounted for rotation around their axes, 3. A separator according to claim 1, characterized in that the bars of the collecting electrode are electrically insulated relative to the housing. Fig.Z Proofreader M.Kucher va