RU2438792C1 - Magnetic separator - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to magnetic separation of various materials and may be used in agriculture for removal of impurities from grain and seed mixes that feature magnetic properties. Magnetic separator comprises two drums arranged one above the other to house stationary magnetic systems, feeder and intake bins. Top drum is mounted to reciprocate in horizontal pane to adjust thickness of processed mix layer.

EFFECT: higher efficiency of separation, electric power savings.

3 cl, 2 dwg

Description

The invention relates to the magnetic separation of various materials and can be used in agricultural production as a working body in the milling industry for the separation of foreign impurities with magnetic properties from grain and seed mixtures, as well as for the separation of metallic ferrous impurities from non-magnetic materials.

Known magnetic separator, including installed in one another with a gap and with the possibility of rotation in one direction, cylindrical drums with parallel generators, the inner surface of the outer of which is intended for transportation, a magnetic system installed in the inner drum, drives to the drums, loading window for feeding material inside the conveying drum and pitched board for receiving the separated fractions, the inner cylindrical drum is installed with an offset to the upper part of the trans porting cylindrical drum.

The disadvantage of a magnetic separator is the complexity of the design and significant energy consumption.

The closest in technical essence is a magnetic separator for separating bulk material, containing a drum with a working surface of non-magnetic material, inside of which there is a magnetic system, a feeder and receivers of separation products, is additionally equipped with a ferromagnetic cylinder fixed inside the drum with an eccentricity with respect to its axis and spinning along with it. The magnetic system is located on the outer surface of the cylinder and is made in the form of separate elements mounted with alternating poles over its entire surface and with a gap between the peripheral edges.

The disadvantage of this device is the low efficiency of cleaning the granular product from ferromagnetic impurities due to slippage of the upper layer of ferromagnetic particles.

The objective of the invention is to increase the efficiency of separation of the mixture from the ferromagnetic component and the exclusion of energy costs.

The solution to this problem is achieved by the fact that in a magnetic separator containing rotatable working bodies and magnetic elements placed therein, a feeder and receivers of separation products, the magnets are placed in thin-walled drums that form a rotating finned cylindrical surface under the influence of gravitational forces of the flow of granular material .

The efficiency of separation of the mixture from the ferromagnetic component is increased due to the fact that due to the use of two working elements sequentially located on opposite sides of the separator housing, with the appropriate selection of the magnetic attraction force, the flow is processed from two sides, which contributes to better separation of the mixture from the ferromagnetic component.

Figure 1 shows a magnetic separator; figure 2 is a section A-A in figure 1.

The magnetic separator comprises a housing 1 having a feeder 2 for the incoming mixture. In the housing 1, shafts 3 and 8 are fixed, on which non-magnetic drums 4 and 9 are mounted on the bearings, with a cylindrical surface with ribs 5 and 10, and in the drums with a minimum clearance the magnetic elements are fixed, which are ferromagnetic half cylinders 6 and 7. In the housing 1, receivers 11 and 13 of the ferromagnetic component are installed, as well as a receiver 12 of a non-magnetic fraction. To adjust the flow rate of the incoming mixture, the housing 1 is equipped with a mechanism 15 with a handle 16 for driving the screw regulators 14 of the longitudinal movement of the drum 4, with the help of which the shaft 3 moves back and forth.

Magnetic separator operates as follows.

The separated mixture from the ferromagnetic component is fed to the feeder 2 located in the housing 1, under the influence of the gravitational flow force, the working bodies 4 and 9 (drums with a finned surface) are brought into rotation by ribs 5 and 10, to the surface of which ferromagnetic particles are attracted by the action of magnets 6 and 7. The drums rotate on bearings mounted on the fixed axes 3 and 8. The ferromagnetic particles then enter the receivers 11 and 13, in which the action of magnetic force ceases, and they fall from the surface of the drum. The non-magnetic fraction, purified of ferroparticles, enters the receiver 12. To increase the throughput of the separator, the drum 4 is moved using screw adjusters 14, rotating the handle 16 of the mechanism 15, increasing the channel passage of the mixture. If necessary, a more thorough cleaning of magnetic particles, the drum 4 is moved in the opposite direction, reducing the thickness of the passing layer of the mixture.

The proposed magnetic separator in comparison with the prototype provides the following technical and economic advantages.

The efficiency of separation of the mixture from the ferromagnetic component increases due to the use of two working bodies sequentially placed on opposite sides of the separator housing, as a result of which the mixture is processed from two sides and contributes to the complete separation of the mixture from the ferromagnetic component.

Electricity is not expended on cleaning bulk material from ferroparticles.

Claims (3)

1. A magnetic separator comprising two drums located one above the other with fixed magnetic systems installed inside them, a feeder and receiving hoppers, characterized in that, in order to increase the efficiency of the separation process and the ability to control throughput, the upper drum is mounted with the possibility of moving back progressively in a horizontal plane to control the thickness of the processed layer of the mixture. 2. The separator according to claim 1, characterized in that the drums are made with a finned outer surface. 3. The separator according to claim 1, characterized in that the separator is equipped with a drive for moving the upper drum.

Images