RU2403978C1 - Washing and cleaning device for metalliferous sand processing - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to ore dressing, particularly to extraction of noble metals. Washing device comprises sand preparation and transfer unit consisting of loading bin, hydraulic washing unit, hydraulic elevator with sluice pipe, coarse gold trap representing a deep filling lock, fine gold trap representing at least two stationary lock-screens with smooth locks with V-shaped bottoms arranged there below, and dressing unit. Additionally, the proposed device comprises suspension-carrying flow solid phase grading and screening and valuable component after-entrapping unit to extract said component from mesh plus of lock-screen representing smooth trough with W-shape bottom. The end of each recess of said bottom has widening slots to withdraw sand heavy fractions to be directed into mesh plus dressing units. Smooth V-shape and W-shape locks are furnished with vertical stilling plates arranged over their entire length, symmetrically on both sides and with clearance with respect to bottom. Stationary lock-screen perforation represents elongated and staggered slots directed along normal relative to lock-screen lengthwise axis. To increase the yield of minor, fine and dust-like particles of heavy noble components, smooth locks with V-shape bottoms feature smooth narrowing of sides. Note here that semi-bottoms of said smooth locks are arranged at an angle each other with smooth decrease in said angle from lock loading to unloading sides from 140° to 100°, while sides of each smooth lock are arranged in plan at the angle to central geometrical axis equal to 6°.

EFFECT: higher yield of fine-grain noble components.

4 cl, 15 dwg

Description

The invention relates to mineral processing, in particular to apparatus for the extraction of precious metals from placers with the associated washing of clay materials from processed products, and can be used to extract other heavy valuable minerals.

Known washing and processing device for clay metal-bearing sands [Hawks K.L. RU 2198032 MPK-9 V03V 5/00, 7/00, published 02/10/2003. Bull. No. 4 (72)].

Signs of a well-known analogue that coincide with the claimed device are: a block for preparing and transporting washed metal-bearing sands, a block for collecting large and medium-sized gold in the form of a deep filling sluice, and a grate-ring sluice.

The disadvantages of this device include the low efficiency of the lock screen, the water cushion created by the small thickness of the sump, as practice has shown, does not provide the required flow vibration and separation of the clay fraction from the stream, as a result, the degree of segregation of solid particles by density is insufficient, the effect of enrichment is very low, although the transporting force of the flow to promote a large fraction of the solid is sufficient; the absence of washing of the solid fraction from the clay material, which transfers the aqueous medium to the rank of a heavy liquid, which reduces the effect of the density during transportation of enrichment and segregation of the suspension. At the same time, an unwanted clogging of the sieves of the sluice-screen is observed, and there is insufficient living area of the sieve openings, and therefore its throughput is small. Hence the observed rather increased drift and washing of the dispersed valuable component into the dump product (tails).

The reason for the lack of efficiency of the industrial device is also the lack of a layered pseudolaminar regime of motion of the suspension flow at high speeds, which causes the loss of grains of a valuable component due to turbulence of the flow.

The washing device ПГНВК / Washing device ПГНВК [patent RU 2080933, MPK-9 В03В 5/00, 7/00, published June 10, 1997, was adopted as a prototype. Bull. No. 16, authors Razdolkin V.N., Yastrebov K.L., Prokopyev S.A.], including a unit for preparing and transporting sand, a unit for collecting large gold and nuggets, a unit for collecting small and thin gold and a unit for collecting a valuable component from the oversize product. At the same time, the unit for preparation and transportation of sand contains a loading hopper, a hydraulic sash, a hydraulic elevator with a slurry line; the large gold recovery unit includes a deep filling gateway. The block for collecting fine and fine gold includes a screen with a pallet, a V-shaped gate for enriching placers, a gravity centrifugal apparatus, for example, a screw separator, a concentration table. The valuable component recovery unit is made in the form of a gutter with a V-shaped bottom, at the end of the axial part of which an expanding slot is made for the output of the concentrate.

The essential features of the prototype, which coincide with the essential features of the claimed device, are: sequentially installed unit for the preparation and transportation of sand, consisting of a loading hopper, a hydraulic puller, hydraulic elevator with slurry line, a large gold recovery unit in the form of a deep filling gate, a small gold recovery unit in the form of at least two fixed, sequentially installed gateway screens with installed smooth locks with V-shaped bottoms and an enrichment unit.

A clear idea of the disadvantages of the prototype can be made based on its work.

Flushing device PGNVK works as follows. The enriched sands supplied by the bulldozer to the unit for preparing and transporting the sands to the receiving grate of the loading hopper are separated by a jet of a hydromonitor on the grating into an oversize fraction (boulder-gravel product larger than 80-50 mm), removed through a hydraulic damper to the dump, and to an under-sieve pulp containing gold. The pulp enters the sump of the loading hopper and, due to the vacuum generated by the hydraulic elevator, is sucked into the receiving chamber and lifted through the pulp line to the coarse gold collection unit into a short deep filling airlock, where coarse-grained heavy fraction, coarse gold and nuggets are caught with stencils and rugs. The resulting concentrate is periodically removed. The tails of a short lock of deep filling containing fine and finely dispersed gold, by gravity enter the block for collecting small and thin gold on a screening sluice with a pallet. The latter is an apparatus that combines the elements of wet screening of a material in a stream with enriching it in density, as practice has shown, does not provide the required vibration of the stream and separation from the stream.

The screen body has the form of a fixed lock with parallel sides and a double bottom (sieve with a flat pallet). The source material through the guide plate enters the upper perforated bottom of the screen. A small product, mainly from heavy minerals, passes through a moving mineral bed, and then through the upper perforated bottom of the screen and enters a flat pallet (to the lower bottom of the screen) and then through the discharge nozzles of the pallet to V-shaped locks and then to the enrichment unit.

The disadvantages of the PGNVK device include the low effective operation of the lock screen: a water cushion created by the small thickness of the sump, clay fraction, as a result, has a low degree of segregation of solid particles by density; the effect of passing enrichment is very low, although the transporting force of the flow to promote a large fraction of the solid is sufficient. This is due to a flaw in the design of the lock screen, which requires the consistent installation of the gutter to capture the heavy fraction of the processed sands. At the same time, there is an undesirable clogging of the round holes of the sieve of the lock-screen and there is an insufficient living area of the holes of the sieve, and therefore its throughput is small. Hence the observed still quite increased drift of fine and finely divided gold due to the influence of the presence of all clay material in the stream, causing the effect of a heavy liquid, the difficulty of adjusting the flows of processed products and keeping in the optimal range of parameters of the water regime - the ratio of liquid to solid W: T, insufficiently high content valuable heavy minerals in the obtained intermediate products and concentrates, the need for transportation in connection with this increased volumes of concentrate for refinement in SHO (Shlihoobogatitelnuyu installation mine) and excessive loading SHOW. Increased liquefaction and, especially, unregulated pulsations of the liquid phase increase the pulsation rate and pulsations of the pulp flow rate on the remaining devices of the industrial device, which worsens the capture of fine gold and increases the additional loss of a valuable component.

The washing device ПГНВК is the closest to the proposed one and is selected as a prototype.

The objective of the invention is to eliminate the above drawbacks without changing the technological scheme, namely, providing the possibility of increasing the extraction of a valuable component of small classes of fineness both in the development of placer deposits and in the processing of epiline fractions and industrial dumps by improving the design of the constituent elements of the industrial device, creating a continuous output concentrate, the possibility of optimal adjustment of the water regime and the hydrodynamic parameters of suspended flows using Vania existing advanced gravity-centrifugal concentrators gearless machines.

The technical result consists in optimizing the hydrodynamics of the washing and enrichment process of metal-bearing sands, providing a pseudo-laminar regime of motion of the suspension flow at high speeds and preventing the loss of grains of a valuable component due to turbulence of the flow, as well as automatic self-regulation of the water process.

The technical result of the claimed invention is achieved by the fact that a flushing device with a continuous output of concentrate, including a sequentially installed unit for preparing and transporting sand, consisting of a loading hopper, a hydraulic puller, a hydraulic elevator with a slurry line, a large gold recovery unit in the form of a deep filling gate, a fine gold recovery unit in at least two fixed, sequentially installed gateway screens with installed smooth gateways with V-shaped bottoms The enrichment unit and the enrichment unit according to the invention are additionally equipped with a unit for classifying and screening the solid phase of the weighed stream and recovering the valuable component from the over-screening product of the sluice-screen, made in the form of a smooth sluice with a W-shaped bottom, at the end of each cavity of the bottom there are expanding slots for the output of the heavy fraction of sand and its direction in the enrichment units of the sublattice product, while in smooth V-shaped and W-shaped locks for their entire length are rigidly installed parallel to their longitudinal axis, s are symmetrical on both sides, two vertical calming plates with a gap relative to the bottom.

The technical result is also achieved by the fact that the perforation of the sieve of the stationary gateway screens is made in the form of elongated slots arranged in a checkerboard pattern with the direction of the slots of the normally longitudinal axis of the lock screen; the distance between the lower edge of the soothing plates and the bottom of smooth sluices with a V-shaped and W-shaped bottom is, for example, 10-20 mm, and soothing plates are fixed on the flow guides (“pyramids”) and by means of transversely arranged at least 2- 3 axles.

To increase the extraction of small, thin and dusty particles of heavy valuable components, smooth locks with V-shaped bottoms are made with a smooth narrowing of the sides, while the middles of smooth locks are located at an angle to each other with a smooth decrease in the angle from the load of the lock to the discharge side from 140 ° to 100 °, and the sides of each smooth lock are located in plan at an angle to the central geometric axis, equal to 6.

The concentrates received from the device are transported in a container way for refinement to a concentrate treatment plant (SHOW).

The compliance of the invention with the requirement of the criterion of "novelty" is determined by the fact that the combination of its essential features is not identical in the development of the industrial instrument circuit and the combination of essential features of the prototype.

The compliance of the invention with the requirement of the criterion of "inventive step" is due to the fact that the combination of its distinctive features, that is, the introduction of improved structural lock screens of two blocks for collecting fine and finely divided gold, smooth locks with a continuous output of concentrate and a chute for collecting heavy fractions, provides an increase in the extraction of a valuable component by 12-15%. The technical solution used to achieve the task is not obvious and does not explicitly follow from the prior art.

The invention is illustrated by drawings, where:

Figure 1. Scheme of the inventive washing and processing device for processing metal-bearing sands (side view).

Figure 2. Scheme of the inventive washing and processing device for processing metal-bearing sand (top view).

Figure 3. Crash gateway (side view).

Figure 4. Crash gateway (top view).

Figure 5. Crash gateway - view from the loading side.

6. Crash gateway - view from the unloading side.

7. Crash Gateway - section I-I.

Fig. 8. Smooth V-shaped gateway - a view in space (in a perspective view).

Fig.9. Smooth V-shaped gateway - side view.

Figure 10. The block of two smooth V-shaped gateways installed under the gateway roar - top view.

11. Smooth V-shaped tapering gateway - side view.

Fig. 12. Smooth V-shaped tapering gateway - view from above.

Fig.13. Smooth W-shaped lock for catching a heavy fraction from the sieve of a lock-screening device - side view.

Fig.14. Smooth W-shaped lock for catching a heavy fraction from the over-screening product of a lock-screen - top view.

Fig.15. Smooth W-shaped lock for catching a heavy fraction from the over-screening product of a lock-screen — section of the lock in AA.

The inventive washing and processing device for processing metal-bearing sand contains the following blocks:

- unit for the preparation and transportation of washed metal sands;

- a block for collecting large and medium-sized gold (including nuggets);

- two consecutively installed identical blocks for collecting fine and thin gold;

- block capture of heavy sand minerals;

- block enrichment of the captured heavy fraction of sand (concentrate processing plant).

Figure 1 and 2 presents a diagram of the inventive washing and processing device for processing metal-bearing sands.

Block preparation and transportation of washed metal sands contains sequentially installed hydraulic monitor 1, hydraulic 2, hydraulic elevator 3 with slurry conduit 4.

The block for collecting large and medium-sized gold (including nuggets) contains a deep filling sluice 5, into the head of which a slurry line 4 is connected.

Behind the block for collecting large and medium-sized gold (including nuggets), two identical and sequentially installed one after another block for collecting small and thin gold are mounted. Each block for collecting fine and thin gold contains a lock-screen and a block mounted under it of two smooth V-shaped locks. Each sluice-screen consists of a docking belt 6, side boards 7, a rear docking belt 8, a connecting plate 9, perforated plates 10, a flat pallet 11 and two discharge pipes 12. A block of two smooth V-shaped locks installed under the sluice-screens, contains guiding the flow of the "pyramid" 13, midday 14, forming a V-shaped bottom, soothing vertical plates 15, a cutoff concentrate 16, the axis of attachment 17 soothing vertical plates 15, the base frame 18, side 19. Under smooth V-shaped gateways set enes concentrating devices such spiral separators 20.

The block for the capture of heavy minerals of sand is installed sequentially after the second block for collecting fine and fine gold (Figs. 13, 14, 15) and contains a smooth W-shaped lock containing: docking plate 21, initial docking belt 22, two sides 23, midday 24, forming the W-shape of the bottom of the airlock, soothing plates 25, axles 26 of the suspension and mounting the soothing plates 25, stiffeners 27, forming a bottom of the airlock, cut-offs of heavy fraction 28.

The enrichment unit for the captured heavy fraction of sand (a concentrator) is located in a separate room and contains: a concentration table 29, a wet magnetic separator 30, a vibrating screen 31, lapping sand and slurry concentration tables 32 and 33, dryers 34 and 35, electric separators 36 and 37.

Figure 3-7 presents a diagram of the gateway screen.

The case of the gateway-screen Figure 3-7 of the inventive washing and processing device for processing metal-bearing sand has the form of a fixed gateway with parallel sides 7 and a double bottom of perforated plates 10. Perforated metal plates 10 are made with slotted perforation, the direction of the slots in a checkerboard pattern is perpendicular to the axis a lock-screen, that is, the direction of the flow of weight. The slotted holes in the perforated metal plates 10 have an expansion inside the pallet to further prevent them from clogging with grains of the processed material. The source material through the connecting plate 9, as a guide, enters the metal perforated plate 10 of the lock-screen. A small product, especially from heavy minerals, passes through a moving mineral bed, and then through perforated metal plates 10 of the sluice screen and enters the flat tray 11 and then through the discharge pipes 12 of the flat pallet 11 to smooth V-shaped locks with a continuous output of concentrate.

In order to increase the classification efficiency with increasing enrichment elements of the granular material of the slurry with a preferred transition to the under-sieve screening product of heavy valuable minerals, the enhanced “whistle effect” is used when numerous (by the number of holes - 10) holes are generated in the stream moving normally to the directions of the slit-like openings of the metal perforated plates 10 perforation slots) and directional vibrations, the parameters of which are a function of size, the number of slotted perforated metal slots plates 10 and the thickness of the flat pallet 11 of the lock-screen, performing the function of the resonator lock-screen. At the same time, the lock-screen is stationary, and the metal perforated plates 10 (sieve) must have milled slotted holes of a certain width and length, perpendicular to the direction of motion of the suspension flow. The combination of a flat pallet 11 and metal perforated plates 10 located in close proximity to each other provides the occurrence of sufficiently strong and numerous plane and synchronous vibrations, causing the metal-bearing part of the solid fraction of the stream to more likely and speed to penetrate through metal perforated plates 10 and further along the plane pallet 11, through the discharge pipes 12 to send for further processing. Thanks to the oscillating water cushion, enough liquid phase (water) remains on the metal perforated plates 10 to transport the large oversize product. The perforated metal plates 10 of the lock screen are supported at the sides on the support corners and in the central part on the central support corners (not shown in the drawings), which at the same time divide the sub-sieve weighing flow in the flat pallet 11 into two parts and direct them to the discharge pipes 12. The work of the gateway screen is characterized by:

- stabilization of the stability of the movement of solid particles in a turbulent suspended flow;

- reducing the viscosity of the slurry near metal perforated plates and stabilizing the motion parameters of the slurry;

- destruction of the embryos of possible structures and providing greater orderliness of the movement of solid particles;

- the direction of the pulsations (oscillations) and the multiplicity (according to the number of slots in the perforated bottom of the lock) of the elementary centers of oscillation generation;

- providing in some respects the effect of jigging, contributing to the capture of a valuable component.

Blocks of two smooth V-shaped gateways are installed under both gateway screens.

The main requirements that ensure the normal course of the enrichment process on a smooth V-shaped gateway Fig-10, are:

- the feed pulp is fed normally to the bottom of the gateway in its axial head to damp the flow rate;

- the pulp is fed to the gateway between two symmetrically located vertical soothing plates 15 with a gap between the lower edges of the plates 15 and the bottom of the gateway 14;

- the upper edge (knife) of the cutter 16 has the same V-shape with an angle slightly larger than the contact angle of the midday 14;

- optimal gateway operation parameters, providing maximum extraction of a valuable component in a collective concentrate, are as follows:

the longitudinal angle of inclination of the lock α = 6 °, the angle of inclination of the midday 14 to the horizon θ = 23 °, the ratio of L (liquid) to T (solid) pulp of the weighted flow L: T = 10 (20): 1, the yield of the concentrate depending on the density the main recoverable component is not more than 10-15% of the initial nutrition; with a lower content of the liquid phase (water), transportation and separation of the solid phase (sand grains) is difficult, with a higher content of the liquid phase (water) the turbulence of the flow will increase and separation of the solid phase during classification by size and segregation by density will become difficult.

In the head part of the smooth V-shaped lock (Figs. 8-10), flow guides (“pyramids”) are symmetrically located 13. Two parallel plates 15 are installed vertically along the longitudinal axis of the smooth V-shaped lock for the entire length of the lock. The distance between the lower edge of the stilling plate 15 and the bottom 14 is sufficient to set 10-20 mm. With a larger gap, calming and flow formation will stop, and with a smaller gap, the latter will become clogged with solid grains and the process of calming and flow formation will stop. Longitudinal soothing plates 15 are mounted on the guide "pyramids" 13 of the flow and using transversely spaced 2-3 axes 17. Smooth V-shaped locks are installed on the base support frame 18 and provided with side sides 19.

A smooth V-shaped gateway works as follows.

The pulp entering a smooth V-shaped lock, guiding "pyramids" 13 is fed into the area between the vertical longitudinal soothing plates 15. The formed flow partially passes under the lower edges of the longitudinal soothing plates 15, forming a weakened transverse wave. The central axial flow significantly disrupts the lateral movement of the pulp and after the formation of the second transverse wave, the flow on a smooth V-shaped gateway acquires a rectilinear motion. In the area of the rectified (formed) flow, heavy fraction is deposited in the lower layers and the enriched part of the flow is cut off at the discharge end of the lock by a cutter 16. The concentrate obtained from smooth V-shaped locks requires subsequent refinement on screw separators 20.

A smooth V-shaped sluice with continuous withdrawal of concentrate for the enrichment of placers allows obtaining rough concentrates of processed sands with a high degree of extraction of valuable minerals. Extraction of particles of heavy minerals with a particle size of up to 0.5 mm is 100%, particle size 0.2-0.5 mm - 100%, particle size 0.1-0.2 mm - 96-98%, particle size 0.050-0.1 mm - 94-96%, particle size 0.03-0.05 mm - up to 90-92%. Additional advantages of performing smooth V-shaped locks of the inventive washing and processing device for processing metal-bearing sands over other devices for gravitational enrichment are high specific productivity, low capital and operating costs and expenses, the absence of moving parts and not the consumption of electricity.

The used structural elements ensured very high-quality alignment and pulp flow formation on smooth V-shaped gateways without any additional devices. The throughput capacity of the lock on solid was: 1) with the source material with a grain size of -4 + 0 mm from 2.2 to 3 m ³ / h (up to 9.4 m ³ / h for 1 m of width or 2.3 m ³ / h for 1 m ^{2 of} working area); 2) at the initial power supply, represented by efels with a fineness of -16 + 0 mm from 3 to 4 m ³ / h (up to 12.6 m ³ / h per 1 m of width or 2.5 m ³ / h per 1 m of working area). The flow velocity on the free surface was 1.8-2.4 m / s. The width of the flow was equal to 300-390 mm with the overall width of the lock 500 mm, the depth along the axis of the flow of 40-75 mm Gold recovery values by size classes are presented in Table 1.

Table 1 Gold recovery by size class. Size classes, mm Recovery (in%) with the size of enriched sand -4 + 0 mm -16 + 0 mm -2 + 1 96.5 97.5 -1 + 0.5 92.0 94.0 -0.5 + 0.25 94.5 73.0 -0.25 + 0.15 57.0 54.0 -0.15 + 0 56.0 47.0

The total extraction of gold into concentrate amounted to 92.6% for sands with a grain size of -4 + 0 mm and 88.7% for the treatment of an epelate fraction with a grain size of -16 + 0 mm. With a gold content in the gateway feed of 0.6 g / m ³ in concentrate and tails, the gold content was 2.985 and 0.052 g / m, respectively, and with a gold content of 1.2 g / m ³ in the initial feed, 8.492 and 0.1362 g / m ³ .

The aforementioned sluice with a smooth bottom 500 mm wide and 4000 mm long provides the enrichment of placer sands with continuous withdrawal of a collective concentrate containing all the minerals of the heavy fraction of sand, including noble metals. The highest enrichment rates are observed at: longitudinal tilt angle of 6 °; tilt the midday to the horizon at an angle of 23 °; liquid to solid ratio W: T = (10-15): 1 and solid productivity not less than 3-4 m ³ / h with a concentrate output of up to 15%.

Industrial (field) tests and long-term monitoring of the operation of these locks showed that, with positive enrichment results, insufficiently high segregation of minerals in longitudinal and transverse directions and the diffusion rate of small and thin particles of heavy valuable minerals into the bottom moving mineral bed are observed. At the same time, an increased yield of concentrate is observed with an insufficiently high concentration of heavy valuable minerals and precious metals.

To maximize the extraction of fine, thin and pulverized gold from the sands of placers, a special case of the refined design of smooth V-shaped locks with a continuous output of concentrate with the arrangement of middles at an angle to each other is proposed (Figs. 11 and 12). A smooth V-shaped tapering airlock with a continuous outlet of the concentrate includes a loading device in the form of a cylindrical pipe for unloading a sluice-screen, located in the upper head of the body of a smooth V-shaped sluice, a case of a smooth V-shaped tapering sluice with inclined half-bottoms 38 installed at an angle to each other, the flow guides of the "pyramid" 39, located in the head of a smooth V-shaped tapering lock under the discharge pipe 12, two longitudinal soothing along the entire length of the plates 40, installed with a gap relative to each other and poludnisch 38 parallel to the axial line of the gateway 41 concentrate cutter mounted in the tail end of a gateway provided with a mechanism adjusting movements along mutually perpendicular axes (not shown).

Smooth V-shaped tapering locks with a continuous output of concentrate are installed on the supporting foundation frame 18 (Fig.11 and 12). A smooth V-shaped tapering lock with an angular arrangement of midday with a continuous output of concentrate works as follows.

The pulp through the discharge pipe 12 is fed into the upper head part of the housing, normally the bottom 38 in its axial part for maximum damping of the speed of movement of the incoming suspension flow. By guiding the flow of the "pyramid" 39, the pulp is introduced on the bottom between vertically mounted longitudinal soothing plates 40, while the generated stream partially passes under the lower edges of the longitudinal soothing plates, forming a weakened transverse wave. The central shaped flow significantly disturbs and dampens the transverse movement of the pulp and after the formation of a second transverse wave of lower amplitude in the region bounded by the plates, the flow on the bottom acquires a rectilinear layered, close to the laminar regime. In the rectified flow zone, heavy grains are deposited in the lower layers of the moving pulp. When moving, there is a “soil exchange” between the flow and the heavy fraction moving along the angular bottom with leaching of most of the light grains of gangue. At the discharge end of the airlock, the heavy fraction of minerals is separated by a concentrate cutter 41 from the entire weight of the suspension stream.

The goal is to increase the extraction of fine, fine and dusty particles of valuable components, i.e. increasing the enrichment depth is achieved by the fact that in the indicated smooth tapering V-shaped lock, the planes of the midnight bottoms are located at an angle to each other, and this angle gradually decreases from loading the lock to the discharge side from 140 ° to 100 °, and the sides of the lock to the discharge side located in plan at an angle to the Central geometric axis, equal to 6 ° (Fig.11-12). Providing in the process of sand enrichment on a smooth V-shaped tapering lock gateway narrowing the flow enhances the segregation of minerals in density in the vertical direction. Segregation is complemented by a process of directed stirring and washing of mineral moving layers with turbulent vortices that lift large light particles located in the upper part of the bottom layer and remove particles of small hydraulic size from the natural layer.

As a result of the interaction of these phenomena in the discharge part of a smooth V-shaped tapering lock in the bottom layers, the concentration of particles of increased density increases, and in the upper layers - low density. The difference in the velocities of the upper and bottom layers of the flow accelerates the removal of waste rock minerals into the tail product. The above allows you to capture and recover heavy minerals and gold with a particle size of up to 30 microns and smaller. The narrowing together with the angular arrangement of the midnight bottoms with a smooth angle change from 140 ° to 100 ° is fundamentally necessary for the process of separation of mineral particles in this gateway.

The indicated one serves as the main means allowing, without additional energy and water costs, to expand the fan of minerals in a vertical plane, to concentrate the heavy minerals in a separate moving part of the stream, and to improve the clipping of the heavy fraction of the processed sands into a concentrate. A considerable advantage of this case of washing and concentrating devices with tapering V-shaped smooth locks is a high specific productivity, low capital costs and the absence of moving parts. The absence of dependence on pulsations of the liquid phase and the automatic self-regulation of the water regime of the enrichment process strengthens the positive aspects of the improved gateway with continuous output of concentrate.

Oversize sluice-screening product (described above - Figs. 3-7), when moving, always mechanically carries away some part of the metal-bearing fraction of sand. To capture mechanically entrained heavy valuable minerals of a weighted flow, it is proposed to use the effect of concentration of the heavy fraction by a gateway with an angular arrangement of midwives - a smooth gateway with a W-shaped bottom 46. As a result, a design of a W-shaped gateway (Figs. 13, 14 and 15) was developed for additional extraction grains of valuable components from the oversize product of the second sluice screen before dumping it into the dump.

The formation and flow quenching in rectilinear locks makes it possible to strengthen the process of separation according to the density of mineral particles with an increase in productivity and throughput of the equipment. Introduction to the design of the angular profile of the bottom, soothing laminarizing laminar flow plates and narrowing of the airlock trench in the plan made it possible to isolate valuable minerals of all size classes into a heavy fraction and thereby increase the concentration depth of dispersed mineral raw materials.

One of the most acceptable processes for cleaning concentrates of locks with an angular profile of the bottom before finishing at the SHOW is the enrichment of minerals in the screw flow of the pulp and on the concentration table.

The inventive washing device operates as follows.

The enriched sands supplied by the bulldozer to the preparation and transportation unit for washed metal-bearing sands to the receiving grate of the loading hopper are washed with a jet of hydraulic monitor 1 on the grating of the hydraulic puller 2 and divided into an oversize fraction (boulder-and-pebble product with a particle size of more than 80 mm) removed through the hydraulic puller 2 in the dump and on an undergrate pulp containing gold. The pulp enters the sump of the loading hopper of the hydraulic sash 2 and, due to the vacuum created by the hydraulic elevator 3, is sucked into the receiving chamber (not shown) and lifted through the slurry line 4 to the recovery unit for large and medium-sized gold (including nuggets) into a short deep lock filling 5, where stencils with rugs (not shown in the drawing) capture a coarse-grained heavy fraction, coarse gold and nuggets. The resulting concentrate is periodically removed. The tails of the deep filling short gate 5, containing fine and finely divided gold, by gravity enter the fine and thin gold collection unit to the screening sluice with a flat pallet 11. The latter is an apparatus that combines elements of wet screening of material in a stream with enrichment by density . The screen body has the form of a fixed lock with parallel sides 7 and a double bottom: perforated plates 10 and a flat pallet 11. The source material enters the metal perforated plates 10 of the lock screen. A small product, mainly from heavy minerals, passes through a moving mineral bed, and then through the perforated metal plates 10 of the sluice screen, it enters a flat pallet 11 (to the lower bottom of the sluice screen) and then through the unloading nozzles 12 of the pallet 11 to smooth V-shaped gateways.

Thanks to the water cushion created by the small thickness of the flat pan 11, part of the water in the sluice screen remains above the metal perforated plates 10 and provides transportation of the oversize product.

An essential feature of the separation by size on this lock-screen with a flat pallet 11 is the predominant allocation of the heaviest minerals into the sublattice product. This is due to the phenomenon of segregation of material in a moving coarse-grained bed. On metal perforated slabs (sieves) of a sluice-screen, material arrives already in a state that has stratified in density and size, in which heavy small grains are in the bottom layer. An additional advantage of a lock screen with a flat pallet 11 and slotted perforation of metal perforated plates 10 is a slight clogging of the sieve holes, low wear of metal perforated plates 10, since the movement of the material occurs at a relatively low flow rate.

Introduction to the circuit diagram of the gateway-screening apparatus with a flat pallet 11 with slotted holes of metal perforated plates 10, as a classifying and processing apparatus, is fundamentally necessary for the extraction of fine and finely divided gold. It is a sluice-screen with a flat pallet 11 that does not consume electricity, which simultaneously provides transportation of an oversized sand and gravel material by a water stream, classification by size of eroded sands, enrichment of sands and extraction of grains of all size classes (smaller than the size of slit holes of sieve perforation) into the sublattice valuable minerals, ensuring optimal dilution of the pulp before feeding it to the V-shaped locks.

But in the inventive washing and processing device for processing metal-bearing sands, part of the heavy fraction can be mechanically carried away by an oversize product. In order to more fully capture the metal-bearing part of the flow, at least one more sluice screen with a flat pallet 11 was sequentially installed, after which the oversize product enters a smooth W-shaped gateway of the tail product with a W-shaped bottom 24, at the discharge end of which an expanding gap is made in the hollows along the axis, through which the fine metal-bearing fraction is captured by means of the cut-off 28 of the heavy fraction.

The under-sieve product of the sluice-screen with a pallet 11 through the discharge pipes 12 enters the upper receiving part of the smooth V-shaped sluice normally bottom 14 in its axial part. At the same time, the speed of movement of the pulp is rapidly extinguished. The height of the sides 19 of the smooth V-shaped gateway by its size prevents overflow even with peak loads. To calm the flow and ensure the direction of its movement in a smooth V-shaped lock, two vertical soothing plates 15 are installed with the possibility of adjusting the relative position and bottom of the lock for the entire length of the lock. At the same time, oblique waves are quenched in the area of these soothing plates 15. Formed axial flow basically does not allow lateral movements of the liquid phase and limits the movement of solid particles. The flow in this case moves rectilinearly in the longitudinal direction in a regime approaching laminar. Along the straightened flow during its movement, 14 grains of a heavy fraction are deposited on the bottom of the airlock. At the end of the smooth V-shaped sluice, the heavy fraction is cut off by a specially designed concentrate cutter 16. The smooth V-shaped sluice performs several functions: straightens, forms and stabilizes the flow, concentrates valuable minerals and hydraulically moves them to the concentrate cutter 16, dehydrates and discharges excess liquid phase and provides the discharge of grains and particles of waste rock into the dump.

These functions prevent the negative effect of irregular flow of the liquid phase on the processing of sand.

The concentrate of each smooth V-shaped sluice, separated by concentrate cutoffs 16, is directed to a gravity-centrifugal apparatus, for example a screw separator 20. The pulp is fed into the upper part of the helical groove (not shown) and, under the influence of gravitational force, moves down the groove (the required height in this case 1.5-2.0 m). Heavy minerals are concentrated closer to the axis of the apparatus, light minerals under the action of centrifugal force and most of the liquid phase are concentrated at the outer side of the screw channel (screw separator). The cutter sends the heavy fraction as a concentrate to a further limit, the light fraction is dumped into the dump.

To complete the extraction of a valuable component, a block for collecting fine and thin gold is additionally installed behind the block for collecting fine and thin gold. Enrichment on it is carried out similarly to the above process.

In this case, the size of the oversize gateway-screening product with a flat pallet is 11 smaller than 80 mm, but larger than 8 mm (-80 + 8 mm). Grains of a valuable component 100% smaller than 2-3 mm are concentrated in the under-sieve product, which allows the over-sieve product to be dumped into the dump.

The difference in density of waste rock and valuable component is more than 6 times. Grains and particles of a valuable component, passing smooth V-shaped locks, concentrate directly at the bottom 14 and move along the bottom to the concentrate cutter 16 to withdraw the concentrate.

Oversize sluice-screening product with a minus 80 + 8 mm particle size can mechanically entrain a certain number of fine grains. In the process of moving from the lock screen to the dump due to peeling, washing and the continuing effect of separation, small grains of the heavy fraction are concentrated and move along the W-shaped bottom 24, and at the end due to an expanding gap in the axial part of the W-shaped bottom 24 , these small grains of heavy minerals and gold are captured by the heavy fraction cutter 28 and are fed by gravity from the heavy sand minerals recovery unit to the screw separators 20 by gravity.

The sludge fraction removed from the screw separators 20 is directed by gravity to the concentration table 29 for cleaning. Concentrate table 29 enters the concentrate treatment plant (SHOW) for subsequent refinement and extraction of valuable components.

In the practice of developing an alluvial deposit, one industrial device can be mounted at the mining site, or the sands are washed with several industrial devices. In the first case, it is advisable to mount the concentration table 29 directly on the industrial device and obtain a “golden head” - the highest concentration of the valuable component and concentrate, which are accumulated in transported containers and then transported to a concentrator for further refinement of the concentrate. In the second case, it is economically feasible to draft rough concentrates (concentrates of gravity-centrifugal apparatuses) to accumulate in containers and transport concentrates of all industrial devices to the central SHOW serving several industrial devices. For cleaning and fine-tuning these concentrates, a larger and more efficient standard size of the concentration table 29 is provided in the head of the central SHOW. Moreover, rough concentrates of industrial instruments by size are completely suitable for processing on the concentration table 29. For this reason, gravitational and gravity-centrifugal devices installed in series end with a concentration table 29 mounted on the flushing device or on the SHOW.

The concentrate of the concentration table 29 is subjected to wet magnetic separation on a separator 30 to separate magnetic minerals into a separate magnetic fraction. The non-magnetic product of the concentrate on the vibrating screen 31 is classified by size. The over-the-top product of the vibrating screen 31 is refined on the sand concentration table 32. After drying in the drying apparatus 34, the concentrate of this table is electrically separated on the electric separator 36 to obtain a gold concentrate. The tailings of the electric separator 36 and the sand concentration table 32 are stored in a special dump.

The sub-sieve product of the vibrating screen 31 is refined on the sludge concentration table 33, the concentrate of which is dried in the drying apparatus 34 and subjected to electrical separation on the electric separator 37 to obtain a gold concentrate. Tail products of the electric separator 37 and slurry concentration table 33 are stored in a special dump.

Gold concentrates are handed over to the gold collection office.

The inventive flushing device is designed, manufactured and tested on current gold-bearing sands.

Claims (4)

1. A washing and concentrating device for processing metal-bearing sands with a continuous output of concentrate, which includes sequentially installed sand preparation and transportation unit, consisting of a loading hopper, a hydraulic hopper, a hydraulic elevator with a slurry line, a large gold recovery unit in the form of a deep filling gateway, a small gold recovery unit in at least two fixed, sequentially installed gateway screens with smooth gateways installed under them with V-shaped bottoms and a heating unit A process, characterized in that it is additionally equipped with a unit for classifying and screening the solid phase of the weighing stream and recovering a valuable component from the over-screening product of the sluice-screen, made in the form of a smooth trough with a W-shaped bottom, at the end of each bottom of the bottom of which expanding slots are made for output the heavy fraction of sand and its direction in the enrichment units of the under-sieve product, while in smooth V-shaped and W-shaped locks for their entire length are rigidly mounted parallel to their longitudinal axis, symmetrically on both sides of the two vertical calming plates with a gap in relation to the bottom. 2. The device according to claim 1, characterized in that the perforation of the sieve of the stationary gateway screens is made in the form of elongated slots arranged in a checkerboard pattern with the direction of the slots of the normally longitudinal axis of the lock screen. 3. The device according to claim 1, characterized in that the distance between the lower edge of the soothing plates and the bottom of smooth sluices with a V-shaped and W-shaped bottom is, for example, 10-20 mm, and soothing plates are fixed on the flow guides "pyramids" and by means of transversally arranged at least 2-3 axes. 4. The device according to claim 1, characterized in that to increase the extraction of small, thin and dusty particles of heavy valuable components, smooth sluices with V-shaped bottoms are made with smooth narrowing of the sides, while the middles of smooth sluices are located at an angle to each other with smooth reducing the angle from the loading of the lock to the discharge side from 140 ° to 100 °, and the sides of each smooth lock are located in plan at an angle to the central geometric axis equal to 6 °.

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