SU889098A1 - Magnetic separator - Google Patents

Description

(54) MACHINE SEPARATOR

I

The invention relates to the enrichment of minerals, in particular, to devices for the magnetic separation of both highly magnetic and weakly magnetic materials of thin classes.

A magnetic separator is known, which includes a working chamber, an electromagnetic system, a feeder, receivers of separation products, cells with ferromagnetic separation 1.

The disadvantage of this magnetic separator is the low efficiency of the separation process of weakly magnetic particles due to the entrainment of magnetic particles with nonmagnetic ones due to the presence in the working area of the magnetic field separator of low intensity, which is not sufficient to separate low magnetic materials, so the working chamber is located not inside the coils, but between the poles of electromagnets.

A magnetic separator is also known, which includes a working chamber with a stack of sieves made of a nonmagnetic material and equipped with magnetic balls, the size of which decreases from the upper sieve to the lower, a magnetic system located on the outer wall of the working chamber, feeder, receivers of separation products 2.

However, this magnetic separator is also characterized by an insufficiently high eff (() efficiency of the process

to slimey weakly magnetic particles, since the working area of the separator is located; not inside the coils, but between the poles of electromagnets, therefore it is hard to create a high-intensity magnetic field

15 in the working area of the separator. In addition, due to shaking, the entrainment of weakly magnetic particles with nonmagnetic particles is possible. As a result, it is not possible to achieve a high e (|) (() 20 separation efficiency of slimey, weakly magnetic materials in this separator.

The aim of the invention is to increase the efficiency of the separation process.

The purpose of the dagger is that the magnetic system is made up of a system of coils with an increasing number of amp-turns from top to bottom, and the sieves are provided with vertical partitions arranged in a checkerboard pattern.

The drawing shows schematically the proposed magnetic separator.

It includes a magnetic system, made in the form of a system of coils I with an increasing number of ampere turns, inside which a working chamber is made of non-magnetic material, which is equipped with magnetic balls 3, the chamber is made in the form of cells 4 of a non-magnetic grid, arranged in a checkerboard pattern. In addition, the separator contains a feeder5 and receivers of separation products 6 and 7 with a gate 8.

The operation of the separator is carried out as follows.

The crushed product containing magnetic particles, in the form of pulp, is fed through the feeder 5 into the working chamber 2. Before feeding the pulp, the coil system is connected to the power supply via direct current sources. Inside the coils, a strong magnetic field of increasing intensity is created due to the increasing number of amber turns. The intensity of the magnetic field is regulated by the amperage. The mechanical gate is positioned to allow the non-magnetic material to be unloaded through the nozzle. At the moment of switching on the electric current, the magnetic balls playing the role of the core of the coil system are magnetized. Magnetic particles are attracted to the magnetized balls and stick to them, and non-magnetic pass between the balls and the cells downwards and enter the receiver of the non-magnetic material 7. The balls, whose diameter decreases from top to bottom, when switched on, the electric current decreases from top to bottom between them, which also contributes to less clogging of the working area of the separator, and, consequently, increase the efficiency of separation. When electric current is turned on through a time relay, the balls are demagnetized, the mechanical gate 8 switches to a position that allows unloading of the magnetic material. The unloading is carried out by a strong pressure of water, which washes away the magnetic particles 1 from the balls, and they enter the receiver of the magnetic material 7.

Thus, the proposed separator makes it possible to increase the efficiency of the separation process in comparison with the known one.

Claims (2)

1. USSR author's certificate No. 580905, cl. At 03 P 1/08, 1973.. 2. USSR author's certificate N9 544466, cl. B 03 C 1 / O8, 1971 (prototype).