RU60397U1 - SEPARATOR - Google Patents

Abstract

The utility model relates to techniques for the extraction of particles from disperse systems (suspensions, colloidal solutions, suspensions) and can be used in mining for the extraction of free metals (gold, platinum, etc.), oxides of most metals, protein substances, etc. . for separation of charged particles, for water purification. Objective: providing the ability to extract small and thin non-magnetic fractions of non-ferrous, rare and precious metals from a mixture of dispersed non-magnetic materials. Essence: a separator containing a loading unit, means for driving the pulp stream, a housing containing channels for separately outputting streams of shared components, means for spatially separating the pulp stream into streams of shared components, made in the form of a magnetic system that contains a current pulse generator and a solenoid, the generator is configured to generate high-power current pulse, a rise time of the pulse current dI (t) / dt of at least 10 ⁸ amps / s asymmetric in time pho current pulses IU, with the duration of the leading edge at the rear, wherein the design parameters of the solenoid taken out conditions to ensure strength of the magnetic field interacting 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 at least 10 ⁶ A / m, with a gradient (grad H) of at least 10 ⁸ A / m ² , in addition, the value of the magnetic field strength in the channel for outputting the stream containing the useful component is 0, and the solenoid placed outside the cavity of the separator body, on its outer wall. 2 ill.

Description

The utility model relates to techniques for the extraction of particles from disperse systems (suspensions, colloidal solutions, suspensions) and can be used in mining for the extraction of free metals (gold, platinum, etc.), oxides of most metals, protein substances, etc. . for separation of charged particles, for water purification.

After processing the rocks in dumps and tails, a significant amount of precious metals remains, mainly in small fractions. Existing devices for the enrichment of gold-bearing ores are not effective enough to maximize the extraction of gold from dumps and placer deposits containing little gold.

A technical solution is known for extracting substances and particles from suspensions and solutions, including a housing with inlet and drain holes, two concentric cylindrical drums installed in the housing, one of which is fixedly mounted, and the other external is mounted for rotation, insulated electrodes connected with a voltage source, characterized in that it is equipped with an additional cylindrical drum mounted motionlessly inside the drums, concentric with them, while inside The third drum is made of metal, the middle and outer drums are made of dielectric, the housing is made with a channel for the extraction of extracted material over which a scraper is installed, and the electrodes are made of rod and are located in the walls of the middle drum along its generators on a part of its surface located from the axis of the inlet housing to the edge of the channel for the output of the extracted material, and the voltage source is located inside the metal drum (see US Pat. RF №2098193, Cl. B 03 C 7/06, 1997).

A feature of the device is that the electrostatic field in the working area of the installation near the surface of the outer drum is created by

edge effects of rod electrodes. There is a field gradient with increasing intensity to the surface of the drum. Therefore, metal particles are attracted to the surface of the outer drum due to Coulomb forces acting in the same direction on the induced charges in the particles.

The disadvantage of this solution is the dependence of its performance on the density of the pulp, in addition, it does not provide the possibility of separating metal particles by type, since the working body removes them from the pulp on its surface, which is then cleaned of adhering particles. In addition, the throughput of the device significantly depends on the area of the gaps through which the pulp passes.

A separator is known, including a cylindrical body with a flat bottom, a slurry receiving chamber located along the axis of the body, devices for outputting heavy and light fractions, characterized in that the cylindrical body with a flat bottom is separated by cylindrical partitions into several chambers, in the bottoms of which are water nozzles supplying water under pressure parallel to the bottom, and the direction of movement of water flows in the conjugate chambers is opposite, the removal of tailings is carried out through the upper edge of the last a single circular chamber into the tail housing with an inclined bottom, the device for the selection of heavy fractions is made in the form of slots located on the bottoms of the chambers (see US Pat. RF No. 2045351, Cl. 03B 5/32, 1995).

The device is a combination of the signs of a continuous centrifugal concentrator (a fixed cylinder with a flat bottom and spiral thread) and a cyclone-type centrifugal concentrator (tangential flow of a water stream under pressure).

However, this device does not fully capture particles with a particle size of less than 0.041 mm, which leads to irretrievable losses of valuable components, are inefficient. Gravity concentrates obtained on the above devices do not differ in high content

valuable components. Bartlez-Mosley locks and Holman lapping tables are more effective devices for enrichment by gravitational methods (Ore dressing guide. Basic processes, - M., Nedra, 1983, p.5-131). But these devices have a very low productivity, occupy large areas, are difficult to operate.

Also known is a separator containing a loading unit, means for driving the pulp stream, a housing containing channels for separately outputting streams of shared components, means for spatially separating the pulp stream into streams of shared components, made in the form of a magnetic system that contains a current pulse generator and a solenoid (see RF Patent No. 2149703, CL B 03 C 1/24, B 03 C 1/26, C 02 F 1/48, 2000). The magnetic system is configured to create a pulsating magnetic field.

The disadvantage of this device is the inability to use it to extract non-magnetic fractions, in addition, it does not provide the ability to extract fine and fine fractions.

The problem to which the invention is directed is to enable the extraction of small and thin non-magnetic 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 boot

site, means for driving the flow of pulp, a housing containing channels for separate output streams of shared components, means for spatially separating the flow of pulp into flows of shared components, made in the form of a magnetic system that contains a current pulse generator and a solenoid, characterized in that the generator is made with to generate a powerful current pulses at a rate of current rise in the pulse dI (t) / dt of at least 10 ⁸ amps / s at the time of asymmetric form of current pulses with a duration of to its front at the rear, wherein the design parameters of the solenoid taken out conditions to ensure strength of the magnetic field interacting with conductive particles (F), in accordance with the expression F ~ σ × r ⁴ × H (t) × dH ( t) / dt, where σ - particle conductivity; r is the linear particle size; H (t) the magnetic field strength is not less than 10 ⁶ A / m, with a gradient (grad H) not less than 10 ⁸ A / m ² , in addition, the value of the magnetic field strength in the channel for outputting the stream containing the useful component is 0, and the solenoid placed outside the cavity of the separator body, on its outer wall.

A comparative analysis of the features of the claimed solution with the signs 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 its interaction with particles of conductive materials moving in the pulp in the latter eddy currents will be induced (in metal particles, due to their high conductivity, eddy currents will ut considerably stronger than in host rock particles which, most often, are good insulators) interaction with inducing

their magnetic field leads to the expulsion of such particles into the 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; figure 2 shows the shape and amplitude of the current pulse generated by the pulse current generator.

The drawings show the loading unit 1, means for driving the flow of pulp 2, casing 3, channels 4 and 5, respectively, for outputting a useful component (concentrate) and tails, a current pulse generator 6 and a solenoid 7, an external wall 8 of the separator.

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

The loading unit 1 is made in the form of a supply pipe connected with a pulp preparation system (not shown in the drawings), which ensures the disintegration of solid material (if necessary, such an operation) and its mixing with water.

As a means of driving the flow of pulp 2, use a pump of known design, preferably a sand, and the formation in the inner space of the casing 3 of a spiral groove 9 (along which the pulp will move to the working area 10 of the solenoid), made with an inclination that allows gravity-free movement of the pulp without sedimentation solid component.

The solenoid 7 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 is perpendicular to the direction of flow of the pulp along the groove 9.

The solenoid 7 is placed on the side of the chute far from the axis of the body, while the channel 4 for outputting the concentrate is located near the side of the chute 9 closest to the axis of the body 3, which ensures “hit of the layer

(flow) ”of the concentrate into channel 4, and channel 5 for outputting tails is located near the side of the trench farthest from the axis of the body.

A mandatory requirement for the solenoid is to maintain operability in the current range of 6 pulse currents coming from the generator, with the possibility of forming a high-gradient powerful pulsed magnetic field with parameters: with an intensity (H (t)) of at least 10 ⁶ A / m, with a change rate (dH ( t) / dt) not less than 10 ⁷ A / m · s and gradient (grad Н) not less than 10 ⁸ A / m ² . The solenoid is placed on the output section of the gutter 9.

As a generator of 6 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 separator works as follows.

The source material (pulp is a suspension in water of a mixture of non-magnetic dispersed materials containing conductive and non-conductive particles, for example, placer material containing particles of rare and noble metals and waste rock) is introduced into the groove 9 of the housing 3 through the feed pipe and gravity moves to the working area 10 solenoid "7. Here, as a result of interaction with a powerful high-gradient pulsed magnetic field, the separated particles, depending on their physical properties, different trajectories of motion are communicated, and For example, gold and platinum-containing alluvial deposits are natural 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 the minerals ( in metallic particles, due to their high conductivity, eddy currents will be much stronger than in particles

enclosing rocks, which, most often, are good insulators). The magnetic field pulses 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 6 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 the space where the magnetic field is weaker - into the layer entering channel 4 (which is ensured by the field inhomogeneity - its high gradient).

When the recession of the external magnetic field begins, the particle begins to drag back. But drags it 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 on a stretch of space lying along the side of the trench close to the axis of the body, and non-conducting particles - tails move along the opposite side of the trench. 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, which ensures their placement in sections of various receiving channels (particles of the host rocks do not interact with the magnetic field and, under the action of centrifugal force, are pressed to the opposite side of the gutter and, accordingly, fall into channel 5 )

If it is necessary to "optimize" the separation process for a specific material, operate with 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 you 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 size of the particle; H (t) is the magnetic field strength; dH (t) / dt rate of change of the magnetic field), and calculate the necessary design parameters of the magnetic system.

A laboratory sample of a separator 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 (1)

A separator comprising a loading unit, a means for driving the pulp stream, a housing containing channels for separately outputting the streams of the separated components, a means of spatially separating the pulp stream into the streams of the separated components, made in the form of a magnetic system that contains a current pulse generator and a solenoid, characterized in the generator is configured to generate high-power current pulse, with a rate of rise of current in the pulse is not less than 10 ⁸ amps / s asymmetric in time pulse shape a current with a duration of the leading edge at the rear, wherein the design parameters of the conditions of the solenoid taken to ensure strength of the magnetic field interacting with conductive particles (F), in accordance with the expression F ~ σ · r ⁴ · H (t) · dH (t) / dt, where F is the force of interaction of the magnetic field with conductive particles, And ⁴ · s / m · kg; σ is the specific conductivity of the particle, A ² · s ³ / m ³ · kg; r is the linear particle size, m; H (t) is the magnetic field strength, A / m; dH (t) / dt is the rate of change of the magnetic field, A / m · s, the magnetic field gradient is not less than 10 ⁸ A / m ² , in addition, the value of the magnetic field strength in the channel for outputting the stream containing the useful component is 0, and the solenoid is located outside the cavity of the separator body on its outer wall.