SU1479108A1 - Device for removing nonmagnetic materials from loose material flow - Google Patents

Abstract

The invention relates to the recovery of non-magnetic metals from a stream of bulk material and increases the efficiency of the process by pushing the metal out of the lower layers of the bulk material. The electromagnetic system (EMC) 1 includes the cores 2 with the coils 3 placed on them. The latter are fixed along the perimeter of the annular frame 4 and have pole tips 5 with alternating polarity around the circumference of the frame 4. Placed above the belt 6 of the EMC conveyor 1 is rotatably mounted around the vertical axis. An additional EMC 7 is placed under the tape 6. It has a magnetic core 8, a coil 9 and pole pieces 10. The placed EMC 7 is perpendicular to the longitudinal axis of the tape 6 and is powered by an alternating current. Under the action of the fields EMC 1 and EMC 7, eddy currents are induced in the volume of metallic impurities present in the bulk material. The magnetic field of these currents interacts with the fields of EMC 1 and EMC 7. As a result, non-magnetic metals present in the bulk material are pushed upward from the lower layers and diverted to receiver 11. 1 sludge.

Description

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The invention relates to the separation of materials according to electrical conductivity in a magnetic field and can be used in mining, metallurgical and other fields of technology for extracting non-magnetic metallic inclusions from various bulk non-magnetic and non-conducting materials.

The object of the invention is to increase the efficiency of the process of extracting non-magnetic metals by pushing them out of the lower layers of the bulk material.

The drawing schematically shows a general view of the device.

The device contains electromagnetic

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aqueous metallic particles are induced by eddy currents. As a result of the interaction of an external ac magnetic field with a field induced in electrically conductive particles, an electromagnetic force arises, pushing the electrically conductive particles towards the weakening magnetic field, i.e., into the upper layers of the material. In this case, non-magnetic particles from the lower layers of the material will be pushed with greater force, as they are located in the region of a stronger magnetic field.

Simultaneously with the buoyant electromagnetic force, the conductive parts of the direct current system 1 include a traveling magnetic field, created by electromagnets consisting of a core given by a rotating electromagnetic 2 with coils 3 placed on them. 2 are fixed along the perimeter of the colloidal particles, they are induced sufficiently tseobraznyi rma 4 and have a pole on the intense eddy currents, the speed of the rotational ends 5 with alternating around the circumference of the electromagnetic system Topic 1 should be 4 r polarity. System 1 is set to be relatively large (on the order of 40 minutes, rotatably above the limit of 50 revolutions per second). As a result of the interaction, the snow belt 6 is used to create a traveling magnetic field, and the belt serves to transport the bulk material. Under the tape 6 in the area of the magnetic system 1 is an electromagnetic system 7, connected to the source of change 25

current (not shown). It contains a laminated magnetic core 8, a coil 9 connected to a source of a passing magnetic field and the field of eddy currents of particles, a horizontal component of the electromagnetic force occurs, under the action of which the nonmagnetic particles move away from the conveyor and enter the receiver 11. The induction of eddy currents into electrically conductive metal in this case, the particles are carried out under the action of an alternating field of the electromagnet current, and the pole pieces 10. 0 n ° of system 7, and under the action of

traveling floor electromagnetic system 1.

Near the tape 6, the receiver 1 of the extracted metal is installed.

The device works as follows.

Coils 3 are connected to a direct current network and electromagnetic system 1 is rotated around its axis. 35 At the same time, the magnetizing coil 9 of the electromagnetic system 7 is connected to an AC network. In this case, in the space between the electromagnetic systems 1 and 7, i.e. the non-formula of the invention

A device for extracting non-magnetic metals from the flow of bulk material, including a feeder, a conveyor belt, an electromagnetic system installed above it to create a traveling magnetic field and receivers of products partitioned directly in the zone where the bulk 40 is located, is not necessary in order to create a material with non-magnetic metal inclusions a magnetic field is created, which is the result of the application of magnetic fields from each of the electromagnetic systems.

The source bulk material containing non-magnetic metallic inclusions is moved along the conveyor belt to the area affected by the magnetic fields of electromagnetic systems 1 and 7. Under the influence of

a high-frequency alternating magnetic Q with the possibility of rotation of a ring-shaped field created by an electromagnetic system, around the perimeter of which are located by subject 7, in non-magnetic, but electro-electromagnets of direct current.

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aqueous metallic particles are induced by eddy currents. As a result of the interaction of an external ac magnetic field with a field induced in electrically conductive particles, an electromagnetic force arises, pushing the electrically conductive particles towards the weakening magnetic field, i.e., into the upper layers of the material. In this case, non-magnetic particles from the lower layers of the material will be pushed with greater force, as they are located in the region of a stronger magnetic field.

Simultaneously with the pushing electromagnetic force, the traveling magnetic field created by the rotating electromagnetic system 1 acts on the electrically conductive particles. In order for the conductive particles to induce sufficiently intense eddy currents, the rotation rate of the electromagnetic system 1 must be relatively large (about 40-50 rev / s). As a result of the interaction

a thick magnetic field and the field of the eddy currents of the particles, a horizontal component of the electromagnetic force arises, under the action of which non-magnetic particles move away from the conveyor, into the receiver 11. The induction of eddy currents in electrically conductive metal particles takes place as under the action of an alternating electromagnetic field th system 7 and under the action

Claims (1)

Invention Formula A device for extracting non-magnetic metals from the flow of bulk material, including a feeder, a conveyor belt, an electromagnetic system installed above it to create a traveling magnetic field and receivers of separation products, characterized in that To increase the efficiency of the process of extracting non-magnetic metals by pushing them out of the lower layers of bulk material, the device is equipped with an electromagnetic system connected to an alternating current source and placed under the conveyor belt perpendicular to its longitudinal axis in the area of the system creating a traveling magnetic field, the latter being performed in the form of