SU1782664A1 - Hydraulic classifier - Google Patents

Description

The invention relates to techniques and technology for the extraction of mica (extraction of small-sized mica from waste mica ore), and can also be used to separate (wash) finely ground (or light) material when separated by size or specific gravity, for example, in the enrichment of sands from clogging silty inclusions .

A known method of extracting large crystals of mica from the ore mass using serial screens equipped with grate sifter surfaces and woven wire sieves. The disadvantage of this technology is that the ore mass with a grain size of 0-20 mm goes to waste, since the ore has high humidity and it is impossible to sow it on sieves with small cells, because sieves stick and clog.

A device for washing minerals is known, the disadvantage of which in relation to the task posed is the loss of small mica plates, which, together with clogging rock particles, are carried into the annular groove.

Also known plate classifier, which is taken as a prototype. The classifier includes a housing, dividing plates, hoppers, the inlet pipe of the original / bullet, distribution manifold for supplying, classifying liquids, pulsation chambers, a source of compressed air.

The disadvantage of the classifier in relation to the task is the low efficiency of extraction of small-sized mica, with a complex process that requires additional energy consumption for the supply of compressed air and classifying fluid. 'The purpose of the invention is to increase the efficiency of the classification of containing mica ore

This goal is achieved by the fact that the classifier is equipped with established and

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1782664. 4 . between the plates above the working level of the pulp dividing walls and installed with the possibility of vertical movement along the plates of the dampers. In this case, the plates are installed with a gap relative to the inclined walls of the bins. In addition, the classifier is equipped with an inclined partition installed above the hoppers and partially overlapping them, some of the plates are connected to the edges of the mating walls of the hoppers, the classifier is also equipped with a rotating drum mounted above the housing with pull ropes attached to the shutters, a package of inclined plates with drain pipes and a pipe for air exhaust installed in the drain pocket below the working level of the pulp, a pipe for controlling the level of the pulp and the housing in horizontal section has the shape of a trapezoid.

Figure 1 gives a General view of the classifier, a perspective view; figure 2 - classifier, a longitudinal section; Fig. 3 is a view A in Fig. 2. +. /:.::

The hydraulic classifier has a chan 1 and supports 2,3. Chan 1 (see Fig. 3 in the plan) from support 2 to support 3 has the shape of a trapezoid (smaller base at support 2) and is divided, for example, by ten plates 4 into eleven zones, where the eleventh zone is a pocket 30 for clarification water. Below the supports 2, 3, a sump 5 with an inclined plane 6 is fixed to the tank 1, in which discharge windows 7,8,9 are made. In the fifth and ninth zones between the walls 4 there are long partitions 10, 11, the upper edges of which are below the working level of the pulp. The partition 10 with the lower edge is docked with the lower edge of the discharge window 8 (on an inclined plane 6). and the partition 11 - with the lower edge of the window 9, thus forming in the sump 5 three tanks 42,13,14, which are collections: 12 - for sedimentation of grain grains, 13 - for sedimentation of plates ^: mica, 14 - for sedimentation of small shroud particles sludge). + · / ·

The discharge window 7 of the tank 12 is blocked by a screw unloader 15 with a drive 16. Below the window 8 of the tank 13, (under an inclined plane 6) is a hopper 17 with a screw unloader 15 with a drive 16. Below the window 9 of a tank 14 (under the inclined plane 6) is a hopper 18 with auger unloader 15 with drive 16.

The second, third and fourth zones of the tank 1 between the plates 4 and the sump 5 are divided by three long partitions 19, the upper edges of which are located below the working level of the pulp in the tank 1, and the lower edges of the partitions form gaps above the inclined plane 6, which are blocked by shutters 20. Partitions 19 with shutters 20 divide the tank 12 into four sections ·. · 21.

The sixth, seventh and eighth zones between the plates 4 in the tank 1 and the tank 13 of the settler 5 are separated by partitions 22, while the lower edges of the partitions form a gap above the inclined plane 6, which is blocked by the shutters 20. The upper edges of the partitions 22 are located below the working level of the pulp. Partitions 22 with shutters 20 divide the container 13 into four sections 23, while the first section of the four is located above the discharge window 8, below which a hopper 17 for collecting 20 mica is placed. '7 77 /+/.+ 7+ ·.

The tenth zone of the tank 1 between the plates 4 and the tank 14 (sump 5) are separated by a partition 24, the lower edge of which is located with a gap above the unloading / 25 window 9, the inclined plane 6, and the upper edge is lower than the operating level of the pool. Trans .. · the town 24 at the bottom is equipped with a long shutter 25 passing through the window 9 into the hopper 18. The partition 24 with the shutter 25 30 divides the tank 14 and the hopper 18 into two sections' 26 ^.: 7 + ^: ·. ^; · / Ό7 '+ ++ - ++ / - ++ / + 7 - / 7. /

So, the upper edges of the plates 4 are located in the upper plane of the tank 1, and the upper edges of the partitions 10,11,19,22,24 35. are located below the upper plane of the tank 1 and slightly below the working level of the pulp in the tank. . . '/ _; +7 7. + 7 /.-·// +

In addition, all plates, partitions and dampers have different widths, increasing + 40 in the direction of expansion of the side walls of the tub 1, which have a trapezoid shape in plan from support 2 to support 3 (see Fig. 3).

On top of the tub 1 is fixed a drum 45 27 with an actuator 28, which is connected by cables (or chains) 29 to the shutters 20, 25.

. In the tub 1 in the last zone in the pocket 30 there is a package of inclined plates 31 containing parallel located 50 plates 32, cavity 33, drain pipe 34 and drain pipe 35. + ++ /

Chan 1 is also equipped with a pipe 36 for feeding (feeding) the pulp and a nozzle 37 for monitoring the working level of the pulp in the tank 1 (and 55 to serve as a sensor for the tracking filling system in the sump 5 in the tank 12 and the first zone with rock grains to the lower edges of the plates 4 ( first four plates).

Hydraulic classifier operation ___ em as follows /

Pulp with wastes of mica ore, containing light thin small plates of mica, which are flat in shape and therefore have significant windage compared to the accompanying heavy grains of rocks, similar in shape to cubic and round geometry with a size of 0-5 mm, is fed into tank 1 through pipe 36 and in a turbulent state passes the receiving zone, fills the tank 12 in the sump 5, goes around the lower edge of the first plate 4, rises up between the first plate 4 and the first partition 19 to the working level of the pulp in the tank 1.

Having made in a turbulent state 15 a sequential alternating vertical direction alternating in the vertical direction (downward), the pulp overflows over the upper edge of the partition 19 in the direction of the next double strokes.

Since the velocity vectors (flow velocity of the fluid and the rate of fall (gravity) of the grains of the material in the fluid) are summed in each section of the double stroke of the vertical flow of pulp, then when the pulp flows down (in the first part of the double stroke), each grain moves down with the resulting total speed but at the same time light, thin, small plates of mica, which have a lamellar (flat) shape and have significant windage and heavy grain grains that are close in shape to a cubic and round geometric shape, vizhutsya down at different rates.

The large difference in the rates of fall of heavy grains of rocks and light small mica plates with windage also determines a different path for the fall of grain grains and a plate of mica in one period of time. Therefore, at the moment when the grain of the rock reaches the bottom of the settler, a thin plate of mica will still be in the way (for example, in the region of the liquid around the bottom edge of the first plate - 4), i.e. there is a delay in the incidence of light mica plates (relative to their suspension in suspension) with the simultaneous active precipitation of heavy rock grains.

And, moreover, at the same time changing the sign of the direction of the liquid flowing upward, when the liquid bends around the lower edge of the first plate 4, in a turbulent active state, the light mica plates are picked up by the fluid flow and are carried up the second section of the double-stroke path, since the speed has expired. liquid upward in this region is greater than the rate of fall of the mica plate in

40.

liquid, i.e., the plate rises up with a resulting speed equal to the difference between the rate of flow of liquid up and the rate of fall of the plate in the liquid.

Thus (using the differences in the geometric shape and mass of the mica plates with sailing and heavy rock grains ^ we have the opportunity to organize active precipitation of heavy grain grains in directed successive vertical descending-ascending double passages during turbulent fluid outflow in the first four zones of the tank 1 of the tank 12 of sedimentation tank 5, i.e., enrich mica plates from clogging grain grains. '

With a further gradual decrease in the flow rate, which takes on a laminar character (since the flow width increases see Fig. 3), we have the possibility, for subsequent, for example, four double strokes of the liquid, to deposit fine small mica plates in the tank 13 of the settler 13 5 to the hopper 17.

With further expiration of the pulp behind the baffle 11 in the last two zones, dusty dust particles precipitate into the hopper 18,

The liquid rises in the last zone (pocket 30) to the working level, at the same time fills the package 31 of the inclined plates 32, where the water is clarified and the smallest polluting particles precipitate, and is discharged through pipes 35 into the water supply system as recycled technical purified water. The presence in the chamber of the plates 31 of the cavity 33 and the drainage pipe 34 and the immersion of the package of plates 31 below the working level of the pulp increases the reliability of the unit for clarification of water, because the rise of the liquid in the bag does not occur due to the vacuum created by the siphon, but due to the rule of communicating vessels, and also prevents the formation of air jams that impede the discharge of purified water.

Unloading of grain grains from the tank 12, mica plates from the tank 13 and from the hopper 17, as well as small parts of the sludge from the tank 14, occurs in the following order.

After the established mode of operation of the classifier, which is determined by filling the tub 1 with pulp to the working level and draining the purified water from the drain pipes 35, as well as filling the reservoir 12 with grains of rocks, for example, from half to two-thirds of the height, turn on the drive 28 of the drum 27 and lift the shutters 20 with cables 29

1782664 8 in the first four zones of the tank 12 and in the second four zones of the tank 13 and the shutter 25 in the tank 14, thus ensuring in the tank 12 the sliding of grain grains along an inclined plane 6 from the zones of the second, third and fourth to the first zone to the screw unloader 15 and the gap between the grain grains between the inclined plane b and the lower edges of the shutters 20, in the container 13, the mica plates slide from the zones of the sixth, seventh and eighth into the fifth zone to the discharge window 8 and then into the hopper 17 with a screw unloader and the gap between the inclined plane 6 and the lower edges of the shutters 20 by mica plates, in a capacity of 14, the slurry slides from the ninth to the tenth zone into the hopper 18 to the screw unloader and the gap is closed by the slurry Between the bottom edge of the shutter 25 and the reciprocal inclined plane of the hopper 18.

The limit of accumulation of materials in containers 12,13,14 is the filling of rocks in the first four zones to the lower edges of the plates 4 and, since the outflow of liquids below will gradually overlap the upper level of the pulp, it will rise above the working level and the liquid will drain into the control pipe 37, which is tracking sensor of the working level of the pulp in the tank 1 and will issue a command to turn on the screw unloaders 15 and the corresponding conveyors transporting materials to warehouses (conveyor not shown).

Number of unloading containers Approximately 40-50% of the drives of screw dischargers are brought to the unloading mode equal to the accumulation of material ’in the respective containers (i.e., the process of extracting mica is ongoing). At the same time, screw dischargers operate under the gap gap between the inclined plane 6 and the lower edges of the shutters 20 covered by materials.

’Thus. ^ Using this hydraulic classifier, we are able to organize the extraction of small mica plates with a size of 0-5 mm from the waste of mica ore, i.e. it was possible to solve a very difficult problem - a more complete extraction of mica during the extraction of a non-reducing very valuable mineral, the need of which is great.

This technical solution will help organize the processing of rock dumps from wastes of mica ores and simultaneously obtain enriched mica of 5 grains of rocks up to 5 mm in size, which are building sands, to ensure the treatment of recycled industrial water * which is of great importance not only economically but also ecologically. environmental protection plan 10.

Claims (7)

Claim 1. Hydraulic classifier, which includes a housing with plates installed in it 16 below the working level of the pulp, located under the housing and connected to its internal space by silos with inclined walls and unloading devices and a drainage truck May 20, with no charge that, in order to increase the efficiency of classifications of mica-containing ores, it is equipped with dividing 25 partitions installed between the plates above the working level of the pulp and installed with the possibility of vertical movement along the pl Astin valves, while the plates are installed with a gap relative to the inclined walls of the bins. thirty , 2. The classifier according to claim 1, with regard to the fact that it is equipped with an inclined partition installed above the hoppers and partially overlapping them. 3. The classifier according to PP, 1 and 2, about l th h a35. The fact that some of the plates are connected to the edges of the mating walls of the bins. 4. The classifier according to paragraphs. 1-3, characterized in that it is equipped with a rotating drum mounted above the housing 40 nom with pull ropes attached to the dampers. 5. The classifier according to paragraphs. 1-4, due to the fact that it is equipped with a package of inclined plates with drain pipes 45 mi and a pipe for air exhaust installed in the drain pocket below the operating level of the remote control. ί 6. The classifier according to paragraphs. 1-5, with the fact that it is equipped with a nozzle for controlling the level of pulp, 7. The classifier according to paragraphs. 1-6, characterized in that the housing in horizontal section has the shape of a trapezoid. 'acbtrnjw # ⁸ bo9v • L / L4? AG. bullets & a (pi / pomspr L & UJars * & __ pe $ ovtbc> 3 / y / W & Ar / rftW * pulp ^ (fJUrntNM / t ·) · mica # peoples Sp * -fiav & 35 33 3Ϋ Cau8 4? Ylkl * 4el <9 ^ 8of6f. yumush U-rrbgli, G1Y4 * G} &