RU2150326C1 - Process and plant for selective opening of thin inclusions of solid material - Google Patents

Abstract

FIELD: analysis of materials. SUBSTANCE: process includes treatment of pulp composed of ground material put in liquid by high-voltage electric discharges. High-voltage nanosecond pulses whose duration is specified by certain dependence are used to treat particles of material with size from some to hundreds micrometers. Plant for realization of process has high-voltage pulse generator, discharge cell with built-in electrodes, unit preparing pulp, unit taking in treated pulp, pipe-lines. Nanosecond generator with pulse repetition frequency in correspondence with specified relation is employed as high voltage generator. Discharge cell with two electrodes is placed in section of flow. One electrode is point that has high-voltage positive polarity and is so positioned that its tip is on axis of cylinder, second electrode is grounded and has form of thin cylinder with outer diameter equal to size of cell. Energy of each pulse is subject to specified relation. Invention makes it feasible to open thin inclusions in particles with size ≤ 1.0 mm. EFFECT: enhanced selectivity of opening of thin inclusions. 4 cl, 2 dwg, 1 tbl

Description

 The invention relates to the grinding process and can be used in mining in the preparation of mineral raw materials for enrichment.

 Known methods of grinding solid material by applying a mechanical load, creating stresses in it that exceed the limits of compressive, tensile and shear strength [1]. Along the directions with such stresses, a solid is destroyed into small particles.

 Mechanical grinding is characterized by random application of the load, which leads to low selectivity of the disclosure of inclusions. The optimum degree of disclosure of inclusions is achieved by refining the raw materials more than three times, which leads to large energy consumption for ore preparation [2].

 The closest technical solutions are electro-pulse and electro-hydraulic grinding methods, which consist in processing the crushed material with electric discharges of microsecond duration with an energy of tens to thousands of joules [3].

 In the electric pulse method, the processing is carried out due to the discharge passing directly through the places of inhomogeneities (inclusions, interfaces, etc.). This is because, at a certain rate of increase in voltage, the electric strength of solid minerals (dielectrics) is lower than the strength of the liquid in which this mineral is located. Electrical breakdown, which leads to the grinding of solid material, occurs mainly at the phase boundary with various properties, which leads to an increase in the selectivity of the process: opening occurs due to pressure in the discharge channel with minimal overgrinding of the starting material.

 With the electro-hydraulic method, the effect is produced mainly by compression and tensile waves that occur in the medium under pulsed electrical breakdown of the pulp (most often a mixture of water with the processed material). This method allows the processing of both dielectric and electrically conductive materials.

 When processing small (less than 1 mm) materials, it is natural that the proportion of electro-hydraulic impact will be decisive, because the transverse size of the discharge channel is very small, from units to tens of microns. Therefore, the fraction of particles trapped in the discharge channel is insignificant.

However, the use of pulses in which energy is released during microseconds does not provide selective disclosure of thin (10 - 1000 microns in size) inclusions, because they create shock waves of microsecond duration. The resulting pressure pulses propagate at a speed of several kilometers per second and effectively act (create tensile stresses) on objects with a characteristic size d> 1 mm, according to the expression
d ≈ 2 • v • t, (1)
where v is the speed of sound in the medium; t is the rise time of the pressure pulse.

 The present invention is to increase the selectivity of the disclosure of fine inclusions in particles with a size of ≤ 1 mm

The problem is solved in that in a method for the selective disclosure of thin inclusions of solid material, including the processing of pulp, consisting of crushed material in the liquid, by high-voltage electric discharges in the breakdown mode, while for processing particles of material with sizes d from units to hundreds of micrometers use high-voltage nanosecond pulses of duration t less than or equal to the double-travel time of a sound wave with velocity v in the particles of the processed material
t ≤ 0.5 • d / v.

To increase the efficiency of opening thin inclusions, the pulp processing area can be limited by a discharge cell made of a material with electrical conductivity less than the electrical conductivity of the pulp, with a cylindrical hole, two electrodes are installed inside the hole on the cylinder axis, and the distance between the electrodes h is chosen from the condition of the breakdown of the pulp, and the diameter of the cylindrical hole D is selected from the condition:
D ≈ h. (2)
To process a continuous pulp stream, the repetition rate of high voltage pulses f is related to the pulp flow rate U _p (cm ³ / s) and the volume of the pulp processing region v (cm ³ ) equal to 0.25 • D ² • h, by the ratio:
f ≥ U _p / _{v. (} 3)
This problem is solved in the installation for the selective disclosure of fine inclusions and for grinding solid materials by electric discharges in the breakdown mode, consisting of a high voltage pulse generator, a discharge cell with electrodes built into it, pulp from the crushed material and liquid, a pulp preparation unit, a processed reception unit pulps, pipelines and valves, as a high voltage generator, a nanosecond generator with a pulse repetition rate according to claim 3, in section They install a discharge cell with two electrodes according to claim 2, one of which a high-voltage positive polarity is a tip and is located so that the tip of the tip is located on the axis of the cylinder, and the second electrode is grounded in the form of a thin cylinder with an external diameter equal to the diameter of the cell , while the processing of the material is carried out by high-voltage pulses according to claim 1, and the energy of each pulse W (J), referred to the unit volume of the processed pulp V _о (cm ³ ), obeys the ratio:
3 ≤ W / V _about ≤ 10.

 Example. The proposed and known methods carried out comparative experiments on grinding gold-bearing pyrite tailings for the enrichment of copper-zinc ores. The average particle size was 50 μm. The selectivity of the disclosure of inclusions of gold particles was determined by the amount of metal transferred to a special solution from the disclosed inclusions. For the first experiment, pulses of 1.5 μs duration were used, and for the proposed experiment, pulses of 15-18 ns duration. In both trials, the processing energy consumption was the same.

 The results of the experiments are presented in the table.

 The results show that in both cases there is a partial disclosure of small inclusions, however, in the proposed method, the efficiency increased by more than 12 times.

Shock waves propagating around the discharge channel decay at a distance of several millimeters from the axis of the channel to values at which the impact on the processed material will not be enough to destroy it. Therefore, to increase the efficiency of the method, it is necessary to limit the area around the breakdown with a wall installed at a distance at which the impact on the processed material will exceed its strength. Due to the rapid attenuation of the compression and extension waves, the volume of the fracture region of the material will be small (≈ 1 cm ³ ); therefore, to increase the efficiency and productivity of the method, pulp processing must be carried out in a continuous flow using generators that allow generating high-voltage nanosecond pulses with a repetition rate of hundreds of hertz . However, the breakdown of the pulp is accompanied by the release of gas bubbles, which must be removed by the flow of pulp from the discharge zone before the arrival of the next pulse. Thus, there should be a correlation between the speed of the pulp and the pulse repetition rate.

In FIG. 1 - shows a setup diagram for explaining the method;
in FIG. 2 - shows a general view of the installation.

 To solve these problems, a discharge cell with a cylindrical hole for passing the pulp of FIG. 1. Cell 1, made of insulating material, with two electrodes, one of which is a high voltage 2 of positive polarity, is a point and is located so that the tip of the point is on the axis of the cylinder. The second electrode 3 is grounded in the form of a thin metal cylinder with an external diameter equal to the diameter of the cylindrical hole of the cell.

 The distance between the electrodes h is chosen from the condition of stable breakdown of the pulp. At a voltage level of 50-250 kV and a pulse duration of less than 50 ns, the value of h lies in the range of 3-6 mm. The diameter of the hole in cell D was found during testing from the condition of greatest efficiency in terms of reducing energy costs for the disclosure of thin inclusions in solid materials. With sufficient accuracy for practical purposes, it was found that D ≈ h.

The repetition rate of high voltage pulses is determined by the ratio:
f ≥ U _p / v
where f is the pulse repetition rate of high voltage; U _p - pulp flow rate (cm ³ / s); V _about - the volume of the treated area (cm ³ ), equal to 0.25 • D ² • h. Relation (2) shows that the flow without gaps passes through the discharge zone, which was confirmed during the testing of the method. Realization of this condition is possible only when using generators with a pulse repetition rate at the level of several hundred hertz. At such a pulse repetition rate, both stable flow passage and high performance of the method are ensured.

During the test method, the following results were obtained:
- to ensure high-quality processing of the material, the pulp flow should be directed from the high-voltage positive electrode to the grounded one. In FIG. 1, the direction of pulp flow is indicated by an arrow. This may be due to the condition of the initiation of a streamer discharge on the positive electrode, the formation of gas bubbles as a result of the breakdown of the pulp, and the further passage of these bubbles in the flow between the electrodes. The opposite direction of flow is characterized by unstable discharges and lower efficiency of the method;
- pulse energy W (J), referred to the unit volume of the processed pulp V _o (cm), obeys the ratio:
3 ≤ W / V _о ≤ 10, (4)
indicating that in this range of specific energies the most effective from the point of view of energy costs is the selective disclosure of fine inclusions and grinding of solid materials.

 The method was implemented in the installation of FIG. 2 for the selective disclosure of fine inclusions and for grinding solid materials by electric discharges in the breakdown mode. The installation consists of a nanosecond high-voltage pulse generator 5, a discharge cell with electrodes 6, 7 embedded in it, a pulp located in the pulp preparation unit 8, a processed pulp receiving unit 9, pipelines 10 and shutoff valves B1, B2. To ensure high-voltage isolation, the generator output electrode and cell are located in a chamber K filled with a liquid dielectric (transformer oil).

 Installation works as follows. In the pulp preparation unit 8, the crushed material and the liquid continuously enter into which they are mixed to produce pulp. When valves B1 and B2 are opened, the pulp moves to the discharge cell and fills the space between the electrodes 6 and 7. At this moment, the generator of high-voltage nanosecond pulses is turned on. 5. The frequency of operation of the generator is selected from condition (3). As a result of electrical discharges between the electrodes 6 and 7 of the discharge cell, compression and extension waves are formed in the pulp solid particles. These loads lead to the splitting of material particles. The splitting mainly occurs at the interfaces between media with different electrophysical properties. This follows from the fact that it is at such boundaries that the shock waves undergo the greatest changes associated with reflection and diffraction. As a result of various strains of various media, the greatest mechanical stresses arise at their interfaces. It is precisely at these boundaries, which have the least mechanical strength, that the material being disintegrated occurs, which leads to the selective disclosure of fine inclusions.

An example of a specific implementation is the installation for the selective disclosure of fine inclusions and for grinding solid materials by electric discharges in the breakdown mode. The installation consists of a nanosecond pulse generator located in a metal tank with a size of 420 x 380 x 200 mm ³ . The generator generates a pulse of positive polarity with an amplitude of about 200 kV, a duration of less than 18 ns, a pulse repetition rate of up to 300 Hz, a pulse energy of 0.3 to 3 J. The output voltage from the generator is applied to the pulsed pulsed processing cell, similar to FIG. 1. Cells with a cylindrical hole diameter D from 3 to 10 mm were used. The pulp preparation unit is a cylindrical vessel with a diameter of 150 mm and a height of 250 mm, in which there is a screw mixer driven by an electric motor. The system is connected by pipelines to valves similar to that shown in FIG. 2.

 Disintegration tests of various materials were carried out at this facility — pyrite tails with an average particle size of 50 μm, mica with particles ranging in size from 100-300 μm, silicon with particle sizes from 10 to 500 μm, etc. In all tests, an increase in the specific surface of materials was observed 15-60%. The efficiency of the disclosure of small particles is shown by the example of pyrite tails (table).

References
1. Selective destruction of minerals V.I. Revnivtsev, G.V. Gaponov, L.I. Zarogatsky and others; Ed. V.I. Revnivtseva. - M .: Nedra, 1998, p. 9.

 2. I.I. Blekhman, G.A. Finkelstein. On the issue of selective disclosure of useful minerals with minimal over-grinding of them. In the book: Improving and developing the process of preparing ores for enrichment. L. Mechanobr. 1975, no. 140, p. 149-152.

 3. A.F. Usov, B.V. Semkin, N.T. Zinoviev. Transients in installations of electric pulse technology.- L .: Nauka, 1987, p. 6-15.

Claims (4)

 1. A method for the selective disclosure of thin inclusions of solid material, comprising treating the pulp consisting of the crushed material in the liquid with high-voltage electric discharges in breakdown mode, characterized in that high-voltage nanosecond nanoseconds are used to process particles of material with sizes d from units to hundreds of micrometers pulses of duration t less than or equal to the double free-wave time of a sound wave with velocity v in the particles of the processed material: t ≤ 0.5 • d / v, (1).  2. The method according to p. 1, characterized in that to increase the efficiency of the disclosure of thin inclusions, the processing area of the pulp is limited by a discharge cell made of a material with an electrical conductivity less than the electrical conductivity of the pulp with a cylindrical hole, two electrodes are installed inside the hole on the cylinder axis, moreover the distance h between the electrodes is selected from the breakdown condition of the pulp, and the diameter of the cylindrical hole D is selected from the condition D ≈ h (2). 3. The method according to claim 1 or 2, characterized in that for processing a continuous pulp stream, the pulse repetition frequency f of high voltage pulses is related to the velocity U _p of the pulp stream and the volume of the pulp processing region v equal to 0.25 • D ² • h, by the ratio f ≥ U _p / v, (3). 4. Installation for the selective disclosure of fine inclusions and for grinding solid materials by electric discharges in the breakdown mode, consisting of a high voltage pulse generator, a discharge cell with electrodes built into it, pulp from the material to be ground and liquid, a pulp preparation unit, a processed pulp receiving unit, pipelines and valves, characterized in that as a high voltage generator, a nanosecond generator with a pulse repetition rate according to claim 3 is used, in the flow cross section establish a discharge cell with two electrodes according to claim 2, one of which, a high-voltage positive polarity, is a tip and is located so that the tip of the tip is located on the axis of the cylinder, and the second electrode is grounded in the form of a thin cylinder with an external diameter equal to the diameter cell, the material is treated with high-voltage pulses according to claim 1, and the energy of each pulse W (J), referred to the unit volume of the treated pulp V _о (cm ³ ), obeys the ratio 3 ≤ W / V _о ≤ 10.

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