RU18239U1 - MAGNETIC SEPARATOR - Google Patents

Abstract

1. A magnetic separator comprising a housing with a ferromagnetic matrix placed therein in the form of a granular nozzle, a magnetizing system and nozzles for supplying a separated and discharging separated medium, characterized in that the magnetic separator is additionally provided with a second housing filled with a ferromagnetic matrix in the form of a granular nozzle having magnetizing system, and in parallel connected inlet and outlet pipelines with the first casing. 2. The magnetic separator according to claim 1, characterized in that the ferromagnetic matrix is made in the form of many soft magnetic balls. The magnetic separator according to claim 2, characterized in that the balls making up the matrix are made of low carbon steel or ferrite. The magnetic separator according to claim 1, characterized in that the magnetization system is made in the form of a solenoid. The magnetic separator according to claim 1, characterized in that the magnetization system is based on periodically opening and closing half cylinders of permanent magnets.

Description

a matrix in the form of a granular nozzle, a magnetizing system and nozzles for supplying a separated and discharging the separated medium, is additionally equipped with a second housing filled with a ferromagnetic matrix in the form of a granular nozzle having a magnetizing system and connected in parallel to the inlet and outlet pipes to the first case.

To increase the efficiency of using the energy of the magnetic field, the ferromagnetic matrix is made in the form of many soft magnetic balls of low carbon steel or ferrite.

The magnetization system can be made in the form of a solenoid or based on periodically opening and closing half cylinders of permanent magnets.

The use of a pair of housings allows the separator to be regenerated without stopping its operation by switching on and off (opening and closing) alternately the first and second magnetization systems.

The design of the device is illustrated in the drawing, which shows a magnetic separator in section.

The magnetic separator consists of two housings (housing 1 and housing 2, respectively) made of non-magnetic materials in the form of cylinders. Each of the cases is filled with a ferromagnetic matrix, respectively 3 and 4, made in the form of a granular nozzle, consisting of soft magnetic balls made, for example, of low carbon steel or ferrite. Magnetization systems designed to create a magnetic field inside the housing 1 and housing 2, can be implemented, for example, in the form of direct current solenoids. The windings, respectively 5 and b of each of the solenoids are connected to the DC circuit through the corresponding keys 7 and 8. Housings 1 and 2 are arranged vertically. Each of them has an inlet pipe (9 for housing 1 and 10 for housing 2) located in the upper part of the housing, through which pulp or flushing water enters the housing and an outlet pipe (11 for housing 1 and 12 for housing 2) located in

pulp or flushing water with a magnetic fraction. The inlet pipes 9 and 10 of the buildings 1 and 2 are interconnected by a horizontal pipe 13, equipped with a pipe 14 through which the pulp is fed into the pipe 13, and by valves 15, 16, 17, 18, The pipe 13 has two inlets 19 and 20, through which rinse water flows into it. The outlet pipes 11 and 12 are connected in parallel by two horizontal pipes 21 and 22 provided with outlet pipes 23 and 24. respectively. Valves 25 and 26 are installed in the pipe 21, located on opposite sides of the outlet pipe 23. Valves 27 and 28 are also installed in the pipe 22. located on opposite sides of the outlet pipe 24. Valves 21-28 automatically open and close the outlet of the pulp or concentrate from the bodies.

Magnetic separator operates as follows.

Valve 16 is open, valves 15, 17, 18 and 28 are closed. The pulp through the pipe 14 through the pipe 13 through the pipe 9 enters the housing 1. Close the key 7 of the DC circuit connected to the coil of the solenoid 5. The magnetic field generated in the coil of the solenoid 5 is amplified by a magnetic matrix 3 by 2-3 orders of magnitude. When the pulp passes through the matrix 3, fine particles of ferromagnetic metals are deposited on the balls. When this valve 27 is open, and the valve 25 is closed. The pulp purified from ferromagnets through the pipe 11 through the pipe 22 and through the pipe 24 flows from the device. As the empty matrix 3 is filled with ferromagnetic particles in the housing 1, the pressure increases. Upon reaching the specified pressure limit, the pulp flows to the housing 2. The valve 16 closes and the valve 17 opens. The valve 27 closes and the valve 25 opens, the valve 26 closes and the valve 28 opens. Open the key 7 of the solenoid winding circuit 5 and close the circuit key 8 windings of the solenoid 6. At the same time, washing with water of the deposited magnetic fraction from the housing 1 into the filter collector (not shown) is turned on, while ensuring regeneration of the matrix. For this, valve 15 is opened and rinse water is supplied under pressure 13 through the inlet 19, which flows through the pipe 9 into the housing 1. Water passes under pressure through the matrix 3

washes away from the balls deposited metal particles on them. Wash water with metal particles through the pipe 11 enters the pipe 21 and through the pipe 23 flows into the filter collector, in which metal particles are removed from the water.

When the specified pressure limit value is reached in the housing 2, the pulp flow switches to the housing 1, and into the housing 2, washing water is supplied through the pipe 13 through the pipe 13 through the pipe 10 and the process is repeated.

The proposed magnetic separator provides the extraction of more than 80% of fine ferromagnetic particles from any fine pulp. Due to the influence of a high-gradient magnetic field, the natural dehydration of peat pulp occurs much faster.

Claims (5)

1. A magnetic separator comprising a housing with a ferromagnetic matrix placed therein in the form of a granular nozzle, a magnetizing system and nozzles for supplying a separated and discharging separated medium, characterized in that the magnetic separator is additionally provided with a second housing filled with a ferromagnetic matrix in the form of a granular nozzle having magnetizing system, and in parallel connected inlet and outlet pipelines with the first housing.  2. The magnetic separator according to claim 1, characterized in that the ferromagnetic matrix is made in the form of many soft magnetic balls.  3. The magnetic separator according to claim 2, characterized in that the balls making up the matrix are made of low carbon steel or ferrite.  4. The magnetic separator according to claim 1, characterized in that the magnetization system is made in the form of a solenoid. 5. The magnetic separator according to claim 1, characterized in that the magnetization system is made on the basis of periodically opening and closing half cylinders of permanent magnets.