RU2132735C1 - Installation for recovery of fine mineral fractions - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: installation for enrichment of placer gold, platinum, and other heavy minerals comprises jigging chamber with diaphragm, immovably mounted cribble joined with bar of vibration drive through bushing, and accumulator for separated fractions. Jigging chamber is provided with pressure control system. Vibration drive bar is provided with, installed in the lower part of bar, aerator-fluffer for fractions being separated. Diaphragm installed on bar free to reciprocate has gasket for bushing and is equipped with blades directed at an angle. Accumulator for separated fractions is disposed in the side of inner surface of jigging chamber. EFFECT: increased fine gold recovery. 2 dwg

Description

The invention relates to the field of enrichment of placer gold, platinum and other heavy minerals with a density of about 15 g / cm ³ and above.

 Known technical solutions that operate on the principle of jigging in the vertical plane of the diaphragm or piston type, which are used in enrichment cycles after deep and fine filling sluices (RF Patent N 2047375, published. 10.11.95).

 These designs in the technological scheme complicate the system, increasing energy consumption and operating costs in the process of mineral processing, thereby reducing efficiency.

 The closest in technical essence and the achieved result is the installation for the extraction of fine mineral fractions, containing a depositing chamber with a diaphragm, a sieve, a drive for separated fractions (RF Patent N 2024317, published. 15.12.94).

 The disadvantages of this device are the inability to work on gateways and the separation of minerals in a narrow range of densities.

 The aim of the invention is to increase productivity, hydrodynamic efficiency of trapping small fractions of minerals and ensuring environmental friendliness.

 This goal is achieved by the fact that in the installation for the extraction of small fractions of minerals "QUANT" containing a depositor with a diaphragm, a sieve, a drive for shared fractions, a depositor is equipped with a pressure control system, and the oscillating drive rod is equipped with a separator for the separated fractions installed in the lower part of the rod , the sieve is installed motionless and connected with the rod of the oscillating drive through the sleeve, while the diaphragm is mounted on the rod of the oscillating drive with the possibility of reciprocating translational motion and supplying a seal to the sleeve, the diaphragm being made with blades mounted at an angle, and the drive of shared fractions is made in the inner surface of the jigging chamber.

 Oscillatory movements of the diaphragm in the vertical direction create an upward hydrodynamic flow in the oversize part, weigh particles of small fractions, creating a three-phase dynamic hydraulic system. Under the influence of natural forces: gravity, hydrodynamic effects of turbulent flow and forced force - upward flow, the adhesion forces relax between the mineral particles of higher density (valuable mineral) and lower density.

 Being in a more balanced state, the particles moving along the sieve, fall into the next phase, in which the vertical component of the forces weakens due to a pause in the movement of the diaphragm, gravitational forces begin to act, particles of a higher density penetrate into the sublattice into the storage ring and into the lower part of the jigging chamber.

 Using the baking powder, after lowering the bar down, a balanced flow of light particles is created, which, gradually rising up, are carried out into the sublattice part.

 The drawings show the installation for the extraction of small fractions of minerals "QUANT".

 In FIG. 1 is a general view of the installation located between the gateway sections, in FIG. 2 is a view A in FIG. 1 - placement of the hydraulic cylinder.

 The installation for the extraction of small fractions of minerals "QUANT" consists of a jigging chamber 1 with a diaphragm 2, a sieve 3 with side walls 4, articulated with sections 5, 6 of the locks on both sides (the front wall in the drawing is not shown) by means of a seal 7. Sieve 3 is installed motionless and has holes 8, the axis of which should be parallel to the axis of the rod 10. In the center of the sieve 3, a sleeve 9 is mounted connecting the sieve 3 with the rod 10 of the oscillating drive 11 with a hydraulic cylinder 12 mounted on the posts 13 and the cross member 14. The posts 13 can be welded to side 4 walls or the base of the installation (not shown in the drawing).

 In the lower part 15 of the rod 10, a baking powder of the separated fractions 16 is installed. The diaphragm 2 is rigidly fixed to the rod 10 of the oscillating drive 11 and is equipped with a seal 17 of the sleeve 9. The diaphragm 2 is made with blades 18 mounted at an angle 19 so that when the rod 10 moves upward, the surface of the blades 18 created an upward flow with torsion of sufficient strength.

 The drive of the divided fractions 20 is made on the inner surface 21 of the depositing chamber 1 along a helical line 22. In the lower part 23 of the depositing chamber 1, a pressure control system 24 is connected.

 The operation of the installation for the extraction of small fractions of minerals "QUANT" is as follows.

 Jigging chamber 1 is mounted on the side walls 4 through 1.5 - 2 meters from the beginning of the lock between sections 5, 6 with a seal 7 (or welded by welding) so that the axis of the rod 10 is perpendicular to the horizontal soil level.

 The oscillatory drive 11 is turned on, and the hydraulic cylinder 12 mounted on the uprights 13 and the cross-member 14 drives the rod 10 passing through the sleeve 9 and the seal 17. The diaphragm 2 quickly moves up. The blades 18, turned plane up at an angle of 19, exert pressure on the liquid layer. Through the openings 8 of the sieve 3, the fluid flows into the sublattice part of the installation. Under the influence of hydrodynamic forces, the energy transferred and transmitted by means of a liquid medium acts on the flow moving along an inclined plane. There is a weakening of the interaction forces between particles of different densities. The denser small particles of minerals go down and, moving through the holes 8, fall on the helical line 22 of the drive of shared fractions 20 of the inner surface 21 and the bottom of the deposit chamber 1. The pause in the movement of the diaphragm 2 following its upward movement allows dense particles under the action of forces gravity to fall down. After a pause, the rod 10 slowly lowers down, loosening the bed of particles in the bottom of the depositing chamber 1 with the aid of the baking powder of the separated fractions 16 in the lower part 15 of the rod 10 so that the lighter particles of empty rock, penetrating down, can rise and with the repeated movement of the diaphragm 2 up, penetrate through holes 8 into the oversize part for removal to the gateway section 6.

 When the empty space is saturated with the space of the sedimentary chamber 1, the sieve 3 is shifted (or part of it is removed) and the upward and downward movement of the rod 10 carries out the empty rock to the airlock.

 The parameters of the oscillatory drive 11 and the blades 18 of the diaphragm 2 are designed so that the force created by the diaphragm 2 by means of the blades 18 and the liquid medium can overcome the adhesion forces between the mineral particles of the material being enriched, and are regulated depending on the composition of the mineral inclusions, the average content of valuable components and the average particle size .

 The pressure control system 24, installed in the lower part 23 of the deposit chamber 1, maintains the working pressure in the deposit chamber 1.

 The installation allows you to increase the extraction of fine gold at the locks in the face of an increasing trend of a decrease in the size of gold and its average grade in placers.

Claims (1)

 Installation for the extraction of small fractions of minerals containing a depositing chamber with a diaphragm, a sieve, a drive of shared fractions, characterized in that the depositing chamber is equipped with a pressure control system, and the oscillating drive rod is equipped with a baking powder of the separated fractions installed in the lower part of the rod, the sieve is fixed and connected with the rod of the oscillating drive through the sleeve, while the diaphragm is mounted on the rod of the oscillating drive with the possibility of reciprocating motion and equipped with a sleeve seal, and the diaphragm is made with blades mounted at an angle, and the drive of the shared fractions is made on the inner surface of the jigging chamber.

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