RU2222383C1 - Washing complex - Google Patents

Abstract

FIELD: beneficiation processes employed for development of placer deposits of mineral wealth, such as gold. SUBSTANCE: washing complex includes feeder, disintegration and classification facilities, water supply system, block of rotary sluice boxes and intake hopper with shower system placed beneath block. Hopper has double walls and presents inclined vessel. Space formed between walls is filled with packages of parallel plates. Outer wall of hopper is equipped with collection pockets. Upper part of vessel is provided with screening surface. Hopper is fitted with transporting tubes located above packages of parallel plates. Transporting tubes are linked to outlet branch pipe of hopper and water supply system. Washing complex is equipped with vibration exciter mounted under packages of parallel plates. It comes in the form of branched blocks of longitudinal-lateral intercoupled bar structures and vibration source. EFFECT: raised operational efficiency of beneficiation equipment thanks to reduced loss of chips and fines of precious component, enhanced ecological reliability of sand washing. 1 cl, 4 dwg

Description

The invention relates to mining and can be used in mineral processing processes in the development of placer mineral deposits, for example, in gold mining.

Known flushing complex (dredge), containing the source pulp feeder, disintegrating and classifying devices, a water supply system, a block of locks (see Shokhin V.N., Lopatin A.G. Gravity enrichment methods. M .: Nedra, 1980, p.305 )

The block of locks used in the known solution captures only a large fraction of a valuable component, and the finely dispersed and most of the small fraction goes into tails. In addition, the removal of concentrate from the catching coatings of the locks reduces the main operating time of the equipment, and an external water treatment system pollutes adjacent natural watercourses.

The closest in technical essence is a complex containing a source pulp feeder, disintegrating and classifying devices, a water supply system, a block of rotary locks with a receiving hopper located under it, which is equipped with an irrigation system and an outlet for concentrate (Myazin V.P., Cherkasov V. G., Karmazin VV Improving the technology of processing gold-containing sands using closed water supply systems for industrial instruments // Mining Journal. - 1996. - No. 9, 10, p.24).

A disadvantage of the known solution is the lack of efficiency in capturing thin and small classes of a valuable component, as well as the pollution of natural watercourses in the mining area.

The technical result of the invention is to increase the efficiency of the washing complex by reducing the loss of small and thin classes of valuable component and improving the environmental reliability of the sand washing system.

The essence of the invention lies in the fact that the washing complex, which includes the feed of the initial pulp, disintegrating and classifying devices, a water supply system, a block of rotary locks and a receiving hopper with an irrigation system and an outlet pipe located under it, is characterized in that the hopper on the pulp outlet side is equipped with a double a wall forming a flat inclined container filled with packages of parallel plates, a vibration exciter installed under the packages of parallel plates, while the outer wall is flax with catch pockets, the upper part of the tank is equipped with a screening surface, and additional nozzles are installed in the lower part of the tank, the hopper is also equipped with conveying pipes located above the packages of parallel plates and connected to the outlet pipe of the hopper and the water supply system.

In addition, the vibration exciter is made in the form of branched blocks of longitudinally transverse rod structures, interconnected with each other and the vibration source.

The installation of a screening surface in the zone of exit of the pulp from the locks allows you to remove a large fraction of waste rock in the tailings, which makes it possible for the cut-off part of the mass flow to reduce the hydrodynamic parameters that affect the drift of the valuable component in the further technological process of separation of the finely divided solid phase.

An inclined tank filled with packets of parallel plates provides a laminar regime of passage of the cut off part of the mass flow of the hydraulic suspension, which creates favorable conditions for the deposition and separation of fine particles.

Outlet nozzles installed in the lower part of the tank allow the silt-clay fraction to be discharged into the tailings, and the clarified water passing through the packages of parallel plates can be turned into circulation, thereby reducing the consumption of fresh water, the volume of soil sedimentation tanks and the concentration of fine particles in them.

An additional installation of the transporting pipes in the tank above the packages of parallel plates and connecting them to the hopper nozzle makes it possible to direct the sediment accumulated in the hopper obtained in the turbulent flow at the locks through the laminar flow into the tank with catch pockets that cut off the waste rock, increasing the concentration of the heavy fraction in the final product.

The installation of a vibration exciter under the packages of parallel plates in the form of branched longitudinal-transverse blocks of rods allows you to cover the surface of the sediment and transport it to the lower part of the tank to the discharge pipe, as well as to transfer the heavy fraction to the lower layer to the outer wall of the tank during vibrotransport, where the installed pockets are cut off a valuable component that previously went into tails.

Thus, the removal of a large fraction of waste rock from the separation process, the reduction of the hydrodynamic regime for the separation of thin classes into sediment, and the control of mass flows together increase the efficiency of the washing complex and its environmental reliability.

Figure 1 shows a washing complex in cross section; figure 2 is the same, a top view; figure 3 is a variant of the connection of the outlet pipes; figure 4 is a section aa.

The washing complex consists of an initial pulp feeder 1, disintegrating 2 and classifying 3 devices, a water supply system 4, a rotary locks block 5, a receiving hopper 6 for sludge from locks, an irrigation system 7, an outlet pipe 8 for removing sediment from the hopper. The hopper 6 has walls 9 and 10, which form a flat inclined tank 11, filled with packages of parallel plates 12, below which is located the vibration exciter 13, Fig.1. The outer wall of the tank 10 is equipped with trapping pockets 14 of the heavy fraction, the upper part of the inclined tank in the zone of pulp exit from the sluices is blocked by a screening surface 15, and the lower one is equipped with nozzles for the exit of recycled water 16 and condensed product 17. In addition, above the packages of parallel plates in the tank are installed conveying pipes 18 connected through regulating devices 19 to the nozzle 8 of the hopper 7 and the water supply system 4, and below the branched blocks 20, Figs. 3, 4, of longitudinally transverse rods connected to the source Ikom vibration 21.

The washing complex operates as follows. The initial pulp through the feeder 1, disintegrating 2 and classifying 3 devices enters the block of rotary locks 5. The settled heavy fraction by periodically turning the locks 5 through an angle of 180 ° with subsequent flushing of the irrigation system 7 enters the hopper 6. The outgoing mass flow from the locks enters the screening surface 15 , where the coarse fraction passes into the tails, and the hydraulic suspension passes into a flat inclined tank 11 and, moving along packets of parallel plates creating a laminar flow, releases a finely divided fraction into a wasp approx. The settled particles move along the outer wall 10 of the tank 11 under the influence of a vibration exciter 13 to the discharge pipe 17. The vibro-transport of the sediment transfers the heavy fraction to the lower layer, which is cut off by the catch pockets 14 and brought out. The sediment from the hopper 6 through the pipe 8, Fig.3, enters the feed pipe 18 and then into the tank 11. Attaching the water supply system to the pipe 18 creates the effect of a hydraulic elevator. The transfer of sediment from the hopper 6 into the tank 11 and its transportation by the exciter 13 through the collection pockets 14 allows you to cut off the waste rock and bring the concentrate out. A thin layer of packages of parallel plates 11 creates favorable conditions for the transfer of clay-clay particles to sediment and clarification of process water.

The creation of an additional technological cycle for separating a hydraulic suspension on the basis of a well-known design allows increasing the depth of extraction of a valuable component by capturing thin classes, the loss of which was, for example, in gold mining 10 ... 50%, and also reducing fresh water consumption by 60 ... 70% by creating a local water treatment loop.

Claims (2)

1. A washing complex containing a source pulp feeder, disintegrating and classifying devices, a water supply system, a block of rotary locks and a receiving hopper located below it with an irrigation system and an outlet pipe, characterized in that the hopper on the pulp exit side of the locks is made with a double wall, forming a flat inclined container and equipped with packages of parallel plates located in the inclined capacity, a vibration exciter installed under the packages of parallel plates, while the outer wall containers are made with catch pockets, the upper part of the tank is equipped with a screening surface, and additional nozzles are installed in the lower part of the tank, the hopper is also equipped with conveying pipes located above the packages of parallel plates and connected to the outlet pipe of the hopper and a water supply system. 2. The washing complex according to claim 1, characterized in that the vibration exciter is made in the form of branched blocks of longitudinally transverse rod structures interconnected with each other and with a vibration source.

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