RU58952U1 - MAGNETIC SEPARATOR - Google Patents

Abstract

The invention relates to the separation of materials by magnetic properties and can be used in the processing of magnetite ores.

The technical result, to which this technical solution is directed, is to increase the efficiency of the destruction of magnetic conglomerates due to the influence of magnetic forces, with a variable radial component and an inverse tangential component when the separated product is moved by a rotating drum relative to the magnetic system.

The magnetic separator includes a shaft-mounted non-magnetic drum 2, bath 3, loading 4 and unloading devices 5, 6, a magnetic system 7 located inside the drum, made in the form of 8 main permanent magnets 9 of a rectangular shape mounted on the magnetic circuit and mounted on the surface of the magnets 9 and made in the form of rectangular prisms of additional magnets 10. The main and additional magnets 9, 10 are made with the same magnetic polarity. The prisms of the additional magnets 10 are made smaller than the main magnets, and are installed in the radial direction with a gap between them. The optimum clearance should be equal to the width of the additional magnets. The main and additional magnets in the direction parallel to the geometric axis of rotation of the drum are placed without a gap, forming continuous parallel strips.

Description

The invention relates to the separation of materials by magnetic properties and can be used in the processing of magnetite ores.

Known magnetic separator, including mounted with the possibility of rotation of a non-magnetic drum, a bath, loading and unloading devices, a magnetic system located inside the drum, made in the form of a permanent rectangular ceramic magnets mounted on a magnetic circuit [1].

However, a disadvantage of the known magnetic separator is its low separation selectivity due to the inefficient use of the inversion zones formed above the round holes in the magnetic blocks.

The technical result, which this technical solution is aimed at, is to increase the efficiency of the destruction of magnetic conglomerates due to the action of magnetic forces with a radial component and a variable inverse tangential component when the separated product is moved by a rotating drum relative to the magnetic system.

This result is achieved due to the fact that the magnetic separator, which includes a non-magnetic drum mounted for rotation, a bath, loading and unloading devices, a magnetic system located inside the drum, made in the form of permanent rectangular magnets mounted on the magnetic circuit, is equipped with

additional magnets mounted on the surface of the main magnets and made in the form of rectangular prisms, the main and additional magnets made with the same magnetic polarity, and the prisms of the additional magnets made smaller than the main magnets, and mounted in the radial direction with a gap between them.

In Fig. 1, a general view of the device, in Fig. 2 is a view A, in Fig. 3 is a schematic view of two magnetic blocks (a view from the end of the drum), in Fig. 4 is a direction diagram of the components of magnetic forces, in Fig. 5 are graphs, illustrating the change in the values of magnetic forces in the radial direction with distance from the surface of the drum.

The magnetic separator includes a non-magnetic drum 2 mounted on the shaft 1 and rotatably mounted on the shaft 1, a bath 3, a loading device 4 and an unloading device 5, 6 located inside the yoke drum 7 with a magnetic circuit 8 on which the main permanent magnets 9 of a rectangular shape are fixed and magnets fixed to the surface 9 and made in the form of rectangular prisms of additional magnets 10. The main and additional magnets 9, 10 are made with the same magnetic polarity. The prisms of the additional magnets 10 are made smaller than the main magnets, and are installed in the radial direction with a gap between them. The optimum clearance should be equal to the width of the additional magnets. The main and additional magnets in a direction parallel to the geometric axis of rotation of the drum are placed without a gap, forming continuous parallel strips.

Magnetic separator operates as follows

The initial ore in the form of pulp through the loading device 4 enters the bath 3, where under the influence of a magnetic field of permanent magnets 9, 10 magnetic

the fraction is attracted to the surface of the non-magnetic drum I and is partially separated from the non-magnetic fraction. When the separated product is moved relative to the magnetic system, additional prismatic magnets create pulsating radial and alternating tangential magnetic forces, leading to the effective destruction of magnetic conglomerates, strands and floccules.

The weakly magnetic fraction is unloaded under the influence of pulp pressure through the unloading device 5. The magnetic product is unloaded through the device 6.

The interaction of the separated product and the magnetic system is illustrated in Fig.3-5. Figure 3 presents two magnetic blocks mounted on a magnetic circuit 8 and consisting of 9 main and 10 additional magnets. On the surface of the rotating drum 2, points A1-A7 are located, near which magnetic forces were measured using a specially made device acting on 1 gram of magnetic concentrate and showing how many times the magnetic force fm exceeds the gravity force ft. (Table 1.)

Table 1. No. A1 A2 A3 A4 A5 A6 A7 fm / Ft, X 0 -twenty 0 +20 0 -twenty 0 fm / Ft, Y +80 +40 0 +40 +80 +30 -twenty

The directions of the components of the magnetic forces correspond to the vector diagram shown in figure 4. Figure 5 presents graphs characterizing the change in the radial component of the magnetic forces with distance from the drum surface R1 and R2 (curve 1 from point A7 and curve 2 from point A5, Fig. 3). The negative values of the magnetic forces on curve 1 illustrate the repulsion of the magnetic product from the magnetic system.

This technical solution is applicable when working with pulps and with dry materials. Magnets (Nd-Fe-Br) are used for weakly magnetic materials, and boron ferrite magnets are used for strongly magnetic materials. The same magnetic polarity of the magnets provides an increase in the depth of extraction, and the presence of additional magnets - an effective cleaning.

Thus, this technical solution will allow:

- effectively destroy magnetic conglomerates, strands and flocculi;

- to provide high selectivity for the separation of separation products.

The source of information

1. Copyright certificate No. 1286288, cl. B 03 C 1/10, 87

Claims (1)

A magnetic separator including a non-magnetic drum mounted for rotation, a bath, loading and unloading devices, a magnetic system located inside the drum, made in the form of rectangular permanent magnets mounted on the magnetic circuit, characterized in that it is provided with fixed magnets mounted on the surface and made in the form rectangular prisms with additional magnets, and the main and additional magnets are made with the same magnetic polarity, and the prisms are additional solid magnets are made smaller than the main magnets, and are installed in the radial direction with a gap between them.