SU1719085A1 - Magnetogravitational separator - Google Patents

Abstract

This invention relates to the separation of materials according to density in a ferromagnetic fluid (PFM). The goal is to increase the efficiency of the material separation process by increasing the time and intensity of the vibration effect on the product. The separator contains a magnetic system 1, in the interpolar gap of which the camera is installed (K) 2. Inside the K 2 there is a PFM 3. There is a plate (P) 4 in the PFZH 3 layer. P 4 is fixed inside the K 2 rigidly. The lateral ends of the P 4 are installed with a gap relative to the walls of the K 2. Slots are cut across the P 4. Surface P 4 is grooved. Rifle directed along P 4 along the flow of material. Inside K 2, equipped with a vibrator, serves a mixture of materials. Light particles float in the volume of FMF 3, and heavy ones sink. The aggregates of the intermediate product are additionally affected by the oscillations of P 4. In this case, the light particles are released and float through the gaps. The industrial product that has fallen under P 4 moves towards the flow of material, and then again slides down the side of the discharge on the surface of P 4. In this way, the time it takes to vibrate the middling is increased. Riffles contribute to the fact that the counter flows of the middlings of heavy particles on the surface of the P 4 do not mix. 1 z.p, f-ly, 2 ill. sl C

Description

FIG. 2

The invention relates to the enrichment of minerals, in particular the separation of minerals and artificial materials in terms of density, and can be used in the processing of ores and secondary raw materials from non-ferrous and ferrous metal alloys.

The purpose of the invention is to increase the efficiency of the material separation process by increasing the time and intensity of the vibration effect on the product.

FIG. 1 shows schematically a separator, a cross-section; in fig. 2 - the same, longitudinal section.

The magneto-gravitational separator includes a magnetic system 1, in the interpolar gap of which a separation chamber 2 is installed with ferromagnetic liquid 3 and a plate 4 of non-magnetic material rigidly connected to the separation chamber 2 and located in the FMF layer parallel to the bottom of the separation chamber with a gap between the side chamber walls, feeder 5 and receivers of separation products 6. Plate 4 has transverse slots and is made wavy in cross section. Thus, it resembles a sheet of building slate, in which cut by transverse slots. At the same time, it can be bent along the longitudinal axis (Fig. 1).

Magnetogravity separator works as follows.

Ferrofluid 3 is poured into separation chamber 2, occupying a certain position under the influence of a magnetic field. Using a feeder 5, the source material is fed into the ferromagnetic fluid layer, which, under the influence of ponderomotive forces in the volume of FMF, is divided into light and heavy fractions. Separated particles under the influence of vibrational oscillations and tilting of the working layer. The FMF moves along the layer, unloading into the corresponding receivers 6. Particles of the industrial production trapped under the plate 4 move towards the flow of light and heavy particles to the end of the plate 4, and being above the plate move like the rest of the particles, in the direction of discharge. Vibration plate 4 contributes to the destruction of industrial products. The presence of slots facilitates the emergence of light particles released from aggregates. The wavy surface contributes to the fact that the flow of heavy particles sliding down plate 4 towards the discharge side does not mix with light particles released from middlings and floating through transverse slots. As a result, the quality of the separation products is improved,

FORUMAWLAH AND ISLANDS

Claims (1)

1. Magnetogravity separator, which includes a magnetic system in the interpolar gap of which a separation chamber of non-magnetic material is installed with vibration, filled with ferromagnetic liquid, the feeder and receivers of separation products, characterized by that. that, in order to increase the efficiency of the material separation process by increasing the time and intensity of the vibration effect on the middling, the separator is equipped with a plate of non-magnetic material rigidly connected to the chamber and located in the ferromagnetic fluid layer parallel to the bottom of the chamber with gaps relative to the side walls of the chamber. 2, the Separator according to claim 1, wherein the plate is made with transverse slots and longitudinal grooves.