SU891155A1 - Electrostatic separator - Google Patents

Description

The invention relates to mineral processing, intended for separation of electrophysical properties of the material and can be used in the industry of construction materials and ^5-negative in the mining industry.

Known electrical separator containing an electrode system consisting of a precipitation drum and high-voltage corona electrodes connected to opposite poles of the current source [1].

The disadvantage of this device is the impossibility of a clear separation of particles 15 by electrophysical properties in an electrostatic field.

The closest to the proposed technical essence and the achieved effect is an electrostatic separator, including a hopper, feeder, precipitation electrode, a high voltage electrode made of conductive elements and a dielectric, receivers of separation products [2]. 25

The disadvantage of this separator is the low efficiency of the separation process.

The purpose of the invention is to increase the efficiency of the separation process for 30 due to the uniform distribution of the material on the surface of the precipitation electrode.

The goal is achieved by placing the conductive elements and the dielectric with alternation and installing them with the possibility of movement relative to the precipitation electrode, and the conductive elements can be made different with increasing thickness from the upper element to the lower.

The drawing shows an electrostatic separator.

The separator includes a hopper 1, a feeder 2, a precipitation drum electrode 3, near which a high-voltage electrode 4 is installed, consisting of conductive elements 5 and a solid dielectric b. The conductive elements are connected to the opposite poles of the electric power source 7. Under the electrodes, receivers of separation products are installed 8. Elements 5 and 6 are mounted with the possibility of their movement relative to each other and relative to the precipitation electrode. The thickness of these elements and their number is determined by the required field configuration. At the ends of the conductive elements, elements 9 with low electrical conductivity can be installed to increase the electric strength of the structure.

The separator works as follows.

Material from the hopper 1 enters the vibratory feeder 2, where the particles receive tribo * charge. Charged material enters the rotating precipitation electrode 3, transporting it to the working area formed by the electrode system.

The high-voltage electrode creates a highly non-uniform field, due to the proposed electrode design, which in some cases allows to increase the difference between the break points of the separated components. In a highly non-uniform field, particles having a larger charge opposite to the charge of the high-voltage electrode 4, under the action of electric and centrifugal forces, break away from the drum 3, and particles having a small charge remain on the drum and leave the working area.

The separator allows immediately before the separation of the material to act on the particles with a field of high tension. If the strength of this field is less than the strength of the field formed by the lower conductive element, then the particles * 0 in the field will oscillate, which leads them to stratification on the drum, depending on their electrophysical properties. The lower element of the electrode serves to deflect particles from the drum. The design also allows you to evenly distribute particles in the drum.

Claims (2)

The invention relates to the enrichment of minerals, is intended for the separation of material according to electrophysical conditions and can be used in the building materials industry and in the mining industry. A known electrical separator containing an electrode system consisting of precipitation drum and high voltage corona electrodes connected to opposite poles of the current source 1. The disadvantage of this device is the impossibility of a clear separation of part according to electrophysical properties in an electrostatic field. The closest to the proposed technical essence and the achievable effect is an electrostatic separator, including a bunker, a feeder, a collecting electrode, a high voltage electrode made of conductive elements and a dielectric, receivers of separation products 2. The disadvantage of this separator is the low efficiency of the separation process. The purpose of the invention is to increase the efficiency of the separation process due to uniform distribution of the material on the surface of the precipitation electrode. The goal is achieved by placing the conductive elements and the dielectric alternating and installing them with the possibility of moving relative to the precipitation electrode, and the conductive elements can be made different in magnitude with increasing thickness from the upper element to the lower one. The drawing shows an electrostatic separator. The separator includes a hopper 1, a feeder 2, a collecting drum electrode 3, near which a high-voltage electrode 4 is installed, consisting of conductive elements 5 and a solid dielectric b. Conductive elements are connected to the opposite poles of the power source 7. Separating products receivers 8 are installed under the electrodes. Elements 5 and 6 are mounted with the possibility of their movement relative to each other and relative to the precipitation electrode. The thickness of these elements and their number is determined by the required field configuration. At the ends of the conductive elements, elements 9 with low electrical conductivity can be installed to increase the electrical strength of the structure. The separator works as follows. The material from the hopper 1 enters the vibrating feeder 2, where the particles receive tribozar e. The charged material enters the rotating collecting electrode 3, transporting it to the working zone formed by the electrode system. The high voltage electrode creates a highly uneven field, due to the proposed implementation of the electrode, which allows in some cases to increase the difference between the separation points of the separated components. In a strongly non-uniform field, particles with a larger charge are opposite to the high-voltage electrode 4, under the action of electrical and centro. The run forces are detached from the drum. 3 particles, which have a small charge, remain on the drum and leave the working area. The separator allows the particles to be subjected to a field of high intensity just before the separation of the material. If the intensity of this field is less than the intensity of the field formed by the lower conductive element, then the particles in the field will oscillate, which leads to their separation on the drum, depending on their electrophysical properties. The lower electrode element serves to deflect the particles from the drum. The design also allows particles to be evenly distributed over the drum. Claim 1. Electrostatic separator, including bunker, feeder, collecting drum electrode, high-voltage electrode made of conductive elements and dielectric, receivers of separation products, in order to increase the efficiency of the separation process due to uniform distribution of the material on the surfaces of the precipitation electrode, the conductive elements and the dielectric are alternately arranged and moveable relative to the precipitation electrode. 2. A separator according to claim 1, characterized in that the conductive elements are of equal size, and their thickness increases from the upper element to the lower one. Sources of information taken into account in the examination 1. The author's certificate of the USSR 543417, cl. B 03 C 7/02, 1973. 2.Oolofinsky N.F. Electric methods of enrichment, M., Nedra, 1977, p. 196 (prototype ;.