SU706126A1 - Rotor polygradient separator - Google Patents

Description

one

This invention relates to the field of mineral processing.

The electromagnetic separator is known, which includes an electromagnetic system, a rotor rotating between its poles with an annular chamber filled with a polyradiation medium, an additional magnetic system located above the rotor in the loading zone of the magnetic fraction, loading i3b iHbie and receiving devices 1.

The disadvantage of this separator is the low degree of regeneration of the polygradient medium.

Also known is a rotary polygradient separator comprising an electromagnetic system with poles, a rotating rotor located between the poles with an annular chamber filled with a polygraphic medium made in the form of a spherical, an additional magnetic system located above the rotor in the discharge zone of the magnetic fraction, a loading device and receivers of separation products 2 .

However, such a separator also does not provide sufficient regeneration of the polygradient medium.

The purpose of the invention is to increase the efficiency of the separation process by improving the conditions for regeneration of the polygradient medium.

This goal is achieved by the fact that the additional magnetic system is made of alternating polarity magnets and is mounted concentric with the rotor.

FIG. 1 shows the described separator in section; in fig. 2 is a view along arrow A in FIG. one.

The separator contains a main electromagnetic system with poles 1 and 2, a rotating rotor 3 with an annular gap, a ferromagnetic environment 4, a loading device 5, grids 6 and 7, limiting the annular gap above and below, receivers of separation products 8 and 9, an additional magnetic system with poles 10 and squirting 11 to supply flush water to the concentrate discharge zone.

The separator works as follows.

The initial power in the form of a water-mineral mixture containing magnetic particles is fed through the loading device 5 into the annular gap of the rotor 3 between the poles of the electromagnetic system 1 and 2. At the same time, non-magnetic particles are freely filtered through a layer of ferromagnetic medium (for example, balls) w are fed to a non-magnetic product. 8. The limiting grating 7 keeps the ferromagnetic medium from falling out of the working gap. The magnetic particles are attracted to the ferromagnetic medium in the contact zone of the constituent bodies (the zone of the high magnetic field gradient) and removed by the rotating rotor from the interpolar gap of the magnetic system. When a ferromagnetic medium enters with the KGEGGNTs of the particles in the neutral) zonelL1octrbmagnetic system, where the intensity of the external magnetic field is 0, the Pbd is sprayed with water, which flushes the magnetic product into the receiver 9. In this annular gap from the splashed 11 additional magnetic system with 10 alternating polar poles. Due to this system, the ferromagnetic environment under it rises, and due to alternating poles, it is loosened, which provides high-quality washing of the magnetic fraction. PenJeTKa 6 keeps the ferromagnetic thread from Attachment to the poles. When the rotor exits. In the neutral zone, the additional magnetic system ends, the ferromagnetic medium is lowered onto the grating 7 and the cleaned enters the interpolar gap of the electromagnetic system.

Performing an additional electromagnetic system with alternating polar poles will increase the efficiency of the separation process by improving the regeneration of the polygradient medium.

Claims (2)

1. US patent number 3375925, class. 209-214, publ. 1966. 2. USSR author's certificate number 275914, cl. At 03 On 1/10, 1968. eight 6 pu-Z.1 Type A .Z