RU57148U1 - SEPARATOR - Google Patents

Abstract

The utility model can be used to extract non-magnetic conductive dispersed materials from a mixture with dispersed non-conductive non-magnetic materials, such as particles of rare and noble metals contained in natural and man-made alluvial deposits. Objective: providing the ability to extract fine and fine fractions of non-ferrous, rare and precious metals from a mixture of dispersed non-magnetic materials. Essence: a separator containing a loading hopper, a receiving tank for conductive particles, a receiving tank for non-conducting particles, a current source and a solenoid, means for supplying the mixture to the magnetic field formation zone, characterized in that the design parameters of the solenoid are made from the condition that the magnetic field interacts with conductive particles (F), in accordance with the expression F ~ σ × r ⁴ × H (t) × dH (t) / dt, where σ is the specific conductivity of the particle; r is the linear particle size; H (t) the magnetic field strength of not less than 10 ⁶ A / m, with a gradient (grad H) of not less than 10 ⁸ A / m ² , while the pulse current generator used to generate powerful current pulses is used as a current source, with the slew rate of the current in the pulse dI (t) / dt is of the order of 10 ⁸ A / s with the time-asymmetrical shape of the current pulses, with the duration of the leading edge of the pulse being less than the trailing edge, in addition, the means for supplying the mixture to the magnetic field formation zone is made in the form of a vibrating feeder driven. In addition, the solenoid is located under the discharge edge of the vibrating feeder. 1 s.p. f-ly, 2 ill.

Description

The utility model relates to the development and enrichment of minerals and can be used to extract non-magnetic conductive dispersed materials from a mixture with dispersed non-conductive non-magnetic materials, such as particles of rare and noble metals contained in natural and man-made alluvial deposits.

A known separator comprising a loading device, a receiving hopper having three compartments: central and side, means for forming a high-frequency electromagnetic field in the working space, the electromagnetic force of which is directed perpendicular to the axis of the mixture flow with the possibility of forming three flows of dispersed materials in the central of which are localized non-conductive particles and in the side conductive particles (see AS USSR No. 784922, Cl. B 03 C 1/02, 1980).

A disadvantage of the known device is the limited range of particle sizes to be separated, due to the low magnitude of the magnetic induction in the working area.

Also known is a separator containing a loading hopper, a receiving tank for conductive particles, a receiving tank for non-conducting particles, a current source and a magnetic field inductor, means for supplying the mixture to the magnetic field formation zone, (see AS USSR No. 1297908, Cl. B 03 C 1/02, 1987).

The disadvantage of this solution is the impossibility of efficiently extracting small and thin particles of non-ferrous, rare and native metals from a mixture of dispersed non-magnetic materials, especially during primary enrichment, when the task is to extract metal particles with a size of 0.1 mm or less.

The problem to which the invention is directed is to enable the extraction of fine and fine fractions of non-ferrous, rare and precious metals from a mixture of dispersed non-magnetic materials.

The technical result achieved in solving the problem is expressed in providing the possibility of almost complete separation (capture of more than 90% of free gold particles with a dimension of 0.1 mm and almost complete capture of fractions up to 0.5 mm) of finely divided non-ferrous rare and precious metals and thereby the possibility creation of effective processing equipment for the primary enrichment of placer deposits of various nature (natural and man-made) in a non-reagent way (i.e. environmentally friendly in terms of emissions reagents to the environment).

The problem is solved in that the separator containing a loading hopper, a receiving tank for conductive particles, a receiving tank for non-conducting particles, a current source and a solenoid, a means for supplying the mixture to the magnetic field formation zone, is characterized in that the design parameters of the solenoid are made from the condition of providing force the interaction of the magnetic field with conductive particles (F), in accordance with the expression F ~ σ × r ⁴ × H (t) × dH (t) / dt, where σ is the specific conductivity of the particle; r is the linear particle size; H (t) the magnetic field strength of not less than 10 ⁶ A / m, with a gradient (grad H) of not less than 10 ⁸ A / m ² , while the current source is a pulse current generator configured to generate powerful current pulses, with the slew rate of the current in the pulse dI (t) / dt is of the order of 10 ⁸ A / s with the time-asymmetrical shape of the current pulses, with the duration of the leading edge of the pulse being less than the trailing edge, in addition, the means for supplying the mixture to the magnetic field formation zone is made in the form of a vibrating feeder driven. In addition, the solenoid is located under the discharge edge of the vibrating feeder.

A comparative analysis of the features of the claimed solution with the features of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The combination of features of the utility model formula provides a solution to the problem - providing the ability to extract fine and fine fractions of non-ferrous, rare and precious metals from a mixture of dispersed non-magnetic materials, since it provides the formation of a powerful high-gradient pulsed magnetic field during the interaction of which with particles of conductive materials, vortex will be induced in the latter currents (in metal particles, due to their high conductivity, eddy currents will be significantly strong than in particles of host rocks, which are most often good insulators) whose interaction with their magnetic field induces them to be pushed into a space where the magnetic field is weaker i.e. to the spatial separation of the mixture into a stream of conductive and non-conductive particles.

The claimed utility model is illustrated by drawings, in which are shown: in Fig. 1 a diagram of an enrichment device (version with a vibratory feeder); figure 2 shows the shape and amplitude of the current pulse generated by the pulse current generator.

The drawings show the loading hopper 1, the chute 2 of the vibrating feeder 3, the solenoid 4, the longitudinal axis 5 of the solenoid, the direction 6 of the action of the magnetic field of the solenoid at the leading edge of the pulse (its increasing section), the generator 7 of the pulse currents, the receiving capacity 8, the waste collection capacity 9. In addition, the layer 10 of the mixture of dispersed non-magnetic materials and the direction 11 of its flow, the direction 12 of the flow of conductive particles, the direction 13 of the flow of non-conductive particles, the direction of motion 14 of the feeder trough are shown.

Structurally named elements of the enrichment device do not differ from known devices used for similar purposes.

The vibrating feeder 3 is a flat bottom chute attached to the base through flat springs and equipped with a drive

movement, which allows each point on the surface of the gutter to make a movement along a closed path transmitted to the particles of the transported material, as vertical and horizontal (along the longitudinal axis of the gutter) reciprocating motion. If it is necessary to separate mixtures containing magnetic materials, the transportation of the dispersed mixture to the working zone 15 of the solenoid can be carried out by a conveyor, such as a belt, or bypassed along an inclined trough or use a rotary feed organ. The solenoid 4 is made in the form of a horizontal row of identical coaxial ring coils of rectangular cross section, in each adjacent pair of which pulse currents of the opposite direction flow. The axis of the coils (longitudinal axis 5 of the solenoid) is perpendicular to the direction of flow of the separated material supplied by the vibrating feeder 3 to the working area of the solenoid 4. The solenoid is mounted on the bracket under the groove of the vibrating feeder, so that the dispersed mixture coming off the groove 2 of the vibrating feeder 3 enters its working zone 15. A mandatory requirement for the solenoid is to maintain operability in the current range of 7 pulse currents coming from the generator, with the possibility of forming a high-gradient powerful pulsed magnetic field parameters: a strength (H (t)) of not less than 10 ⁶ A / m, when the rate of change (dH (t) / dt) is not less than 10 ⁷ amp / m · s and the gradient (grad H) is not less than 10 ⁸ amps / m ² .

As a generator of 7 pulsed currents, you can use a pulse current generator with a capacitive energy storage and thyristor, as a current chopper. The rate of increase of current in the pulse dI (t) / dt) is not less than 10 ⁸ A / s (which allows obtaining dH (t) / dt in the solenoid) of the order of 10 ⁶ -10 ⁷ A / m · s). The shape, amplitude and duration of the current pulse of the generator are shown in figure 2.

The claimed method is implemented as follows.

A mixture of non-magnetic dispersed materials containing conductive and non-conductive particles (for example, alluvial material containing rare and noble metal particles and waste rock) is fed by gravity

from the feed hopper 1, into the chute 2 of the vibrating feeder 3, and due to the directed vibrations of the latter, it “spreads” into a relatively thin layer 1, and also moves in the direction 11. Having reached the edge of the groove 2 of the vibrating feeder 3, the mixture of non-magnetic dispersed materials falls down, getting 15 solenoid 4 into the working zone 4. Here, as a result of interaction with a powerful high-gradient pulsed magnetic field, the particles being separated, depending on their physical properties, various motion paths are communicated, and their simple anstvennoe division. For example, gold- and platinum-containing alluvial deposits are naturally dispersed mixtures of minerals in which free metal particles differ from the host rocks in their high electrical conductivity. When exposed to such a mixture by a pulsed magnetic field, eddy currents will be induced in the particles of minerals (in metal particles, due to their high conductivity, eddy currents will be much stronger than in particles of host rocks, which are most often good insulators). The pulses of the magnetic field have an asymmetric shape - a steep rise (leading edge) and a gentle slope (trailing edge), corresponding to the shape of the current pulses generated by the generator 7 pulse currents. During the growth of the external magnetic field pulse, a strong eddy current is induced in the particles (moreover, the magnitude of this current is the greater, the faster it grows, the external magnetic field changes in time). Eddy currents in metal particles interact with a magnetic field inducing them and the particle is pushed into a space where the magnetic field is weaker (which is ensured by the inhomogeneity of the field - its high gradient).

When the recession of the external magnetic field begins, the particle begins to drag back. But drags her back with less force, because the trailing edge of the pulse is gentle (changes more slowly over time), and the particle continues to move after the end of the pulse in the area of space lying

along direction 12 (at a distance from direction 13 along which non-conducting particles move). In addition, by the time the magnetic field decays, the metal particles are already at a considerable distance from the solenoid and can no longer return to the general flow.

After a sufficiently large number of pulses, a spatial separation of the flows of conductive and non-conductive particles is achieved (their trajectories are 12 and 13, respectively), which ensures their placement in different receiving tanks (particles of the host rocks with a magnetic field practically do not interact and fall into the waste collection tank 9 located directly below the edge of the chute). If it is necessary to “optimize” the separation process for a specific material, they use data on the specific conductivity of the particle material and its particle size, using the mathematical expression specified in the utility model formula, which allows one to determine the required value of the interaction force (F ~ σ × r ⁴ × H (t ) × dH (t) / dt, where σ is the specific conductivity of the particle; r is the linear particle size; H (t) is the magnetic field strength; dH (t) / dt is the rate of change of the magnetic field), and calculate the necessary design parameters of the magnetic system.

To test the performance of the proposal, experiments were conducted with artificial mixtures of minerals composed of quartz sand with a grain size of 0.5 to 0.1 mm and sawdust of copper, aluminum and brass, with a grain size of 3.0 to 0.1 mm. Mixtures were not classified so that it was immediately apparent what particle sizes were recovered. As a result of the experiments, it turned out that in the extracted material there are particles of all metals and all particle sizes, including 0.1 mm class. The bulk of the extracted metal is made up of particles of classes 0.5-0.2 mm, and aluminum particles are pushed out by a magnetic field further than brass and copper. This is due to the fact that aluminum has a conductivity of only slightly less than copper, and the density is three times lower. Light particles are pushed further.

A laboratory sample of an apparatus operating on this principle has been tested. Tests have shown the efficiency of the method and the possibility of its implementation in the framework of the currently existing technical means.

The device allows you to reliably remove from the placer gold particles of 0.1 mm or other more easily recoverable materials. The most effective area of its use is the processing of dumps (it is known that when developing placers by traditional methods, fairly large fractions (more than 0.5 mm) are well extracted, and, which is smaller, it goes to dumps when washing (according to various estimates, it takes ~ 40-60% gold).

Claims (2)

1. A separator containing a loading hopper, a receiving tank for conductive particles, a receiving tank for non-conductive particles, a current source and a solenoid, a means for supplying the mixture to the magnetic field formation zone, characterized in that the design parameters of the solenoid are made from the condition that the magnetic field interacts with conductive particles (F), in accordance with the expression F ~ σ × r ⁴ · H (t) · dH (t) / dt, where σ is the specific conductivity of the particle; r is the linear particle size; H (t) is the magnetic field strength of at least 10 ⁶ A / m, with a gradient (grad H) of at least 10 ⁸ A / m ² , while the current source is a pulse current generator configured to generate powerful current pulses, with the slew rate of the current in the pulse dI (t) / dt is of the order of 10 ⁸ A / s with the time-asymmetrical shape of the current pulses, with the duration of the leading edge of the pulse being less than the trailing edge, in addition, the means for supplying the mixture to the magnetic field formation zone is made in the form of a vibrating feeder driven. 2. The separator according to claim 1, characterized in that the solenoid is located under the discharge edge of the feeder with a vibratory drive.