RU58951U1 - PLANT FOR HYDROCLASSIFICATION OF POLYDISPERSION GRAIN MATERIALS - Google Patents

Abstract

The utility model relates to devices for separating solid polydisperse materials according to the boundary particle size in a liquid medium and can be used in mining, chemical, metallurgical and other industries, as well as in the production of building materials. At the proposed installation, it is possible to obtain up to eight different fractions of high uniformity of sand of different classes. The installation contains a cascade of three classification modules installed in series and hydraulically interconnected, each of which includes a receiving and separating unit, consisting of a hydraulic screen and two cylinder-conical hydroclassifiers, equipped with laminarization units at the lower outlet. Hydroclassification is carried out as follows: particles of the classified material are fed as a slurry to the diffuser inlet 28 of the hydroclassifier 22 from top to bottom, deposited in its cylindrical part, where they meet the speed-calculated for this classifier with the flow of clean water supplied from the bottom up from the laminarization unit 31. High-speed the water flow mode is designed to maintain the speed of particles soaking up to the maximum size of the selected fraction, while the particle deposition rate decreases to such a value, In which large particles cannot be carried up and hang at the junction of the bottom of the classification chamber of the hydroclassifier 22 and pipe 68 of the laminarization unit 31, forming a “fluidized bed”, and small particles are carried upward by a stream of water, discharged into pipeline 29 and sent to the next classification stage . In the process of “boiling”, large particles of a given fraction intensively move in a horizontal plane above the nozzle 68, forming a layer that begins to grow and increase in thickness, while the permeability of the layer to the water flow decreases. Due to the imbalance between the mass of the layer and the pressure of the water underneath, a pulse breakthrough of the layer occurs with a column of water with a simultaneous sharp decrease in the velocity of the upward flow in the adjacent zone around the water column and the oscillatory process of self-equalization of the velocity of this stream. Particles floating in the "fluidized bed" uniformly accelerate in the form of a bound flow into the nozzle 68. During a brief violation of the speed regime of the upward flow of water in the nozzle 68 of the laminarization unit 31, the sedimentation rate of the specified large particles of the layer has time to exceed the speed of the upward flow restored to the specified value, they settle to the bottom of the tank - the receiver

67 of the laminarization unit 31, and then through the pipeline 32 are put on the map, as the final product, and smaller particles, when deposited falling into the restored up to a predetermined value, do not have time to develop their deposition rate greater than the speed of the upward stream and are carried up the pipe 68 into the cylindrical reception and separation chamber of the hydroclassifier and then through the pipeline and to the diffuser inlet of the next hydroclassifier to highlight the next desired fraction. 10 zpf 2. FIG.

Description

The utility model relates to devices for separating solid polydisperse materials according to the boundary particle size in a liquid medium and can be used in mining, chemical, metallurgical and other industries, as well as in the production of building materials.

A known installation for the gradual hydroclassification of granular materials, including metal with a hopper-feeder installed on it and several sections located one below the other, consisting of classifying cylindrical tanks and drain chambers, the cross-sectional areas of each of which increase from top to bottom inversely to the hydraulic grain size of the graded grains material, outlet pipes for condensed products of classification, metal construction is made in the form of a closed tubular systems with the possibility of supplying water to it from the main conduit, to which the supporting saddles of cylindrical containers are fixed, and is equipped with pipes for supplying water to each of the cylindrical-conical tanks for their filling and washing (RU No. 2166996 V 03 V 5/62, V 03 V 7 / 00 publ. 10/05/2001)

A disadvantage of the known installation is the low quality of the obtained product, which consists in insufficient homogeneity of the obtained fractions according to the particle size distribution, especially the fine fraction of the granular material released and in the incomplete separation of organic and inorganic impurities.

The proposed utility model solves the problem of improving the quality of the resulting product while enhancing the classification process and ensuring its continuity.

This problem is solved in that the installation for hydroclassification of polydisperse granular materials contains a cascade of three classification modules installed in series and hydraulically interconnected, each of which includes a receiving and separating unit, which is a hydraulic screen of a cylindrical shape with a tangential inlet in the upper cylindrical part for feeding hydraulic mixtures and a lower outlet in the conical part, and two hydroclassifiers comprising a housing consisting of a cylindrical receiving section Call duration and classification conical chambers, slurry inlet, an outlet for withdrawal of fine fraction set at reception of the separation chamber, and nozzle

for outputting the target fraction, installed in the lower part of the classification chamber, all hydroclassifiers are equipped with a laminarization unit, which is a construction in the form of a conditional tee, consisting of a receiver tank into which the first part of the tee is lowered by 1/4 of its height along the central vertical axis - cylindrical vertical pipe, which is combined with the lower output of the hydroclassifier, the second part of the tee - the inlet pipe with a jet straightener is set at 2/3 of the tank height - receiver, is designed for introducing the working fluid through the tank - the receiver into the conical part of the hydroclassifier and the third part of the tee - the outlet pipe installed diametrically to the jet straightener at 1/3 of the height of the tank-receiver

The ratio of the cross-sectional area of the pipes of the laminarization unit P _under : F _in : P _out = 1.0: 0.18: 0.08, where:

F _under - the cross-sectional area of the outlet pipe for supplying clean water to the hydroclassifier;

F _in - the cross-sectional area of the inlet pipe for supplying clean water to the tank-receiver;

_Fout - the cross-sectional area of the outlet pipe for outputting the target fraction from the hydroclassifier through the receiver tank.

The straightener is a nozzle with radial plates placed inside, dividing the cross-sectional area of the nozzle into 4 ÷ 8 equal sectors.

The hydraulic screen of the first separation module further includes an upper outlet pipe for the removal of small fractions, made in the form of a siphon, which is lowered into the housing of the hydraulic screen by 1/3 of its height along its central vertical axis, and the lower outlet through a tee is connected to the upper tangential inlets of two hydroclassifiers representing hydrocyclones.

The upper exits of the hydro screen and the first hydrocyclone are connected via a control valve to the inlet of the hydro screen of the third classification module, and the upper output of the second hydro cyclone is connected by a pipe through the control valve to the hydro screen of the second classification module.

Pipes for withdrawing the target fraction from the laminarization units of the first classification module are connected to pipelines made in the form of a water seal by u-shaped bending and raising the upper point to the level of 0.9 ÷ 0.95 of the level of connection of the laminarization unit with the tangential inlets of hydrocyclones.

The hydraulic screen of the second classification module is equipped with a grid placed in the conical part and a hatch for removing debris, the height of the cylindrical part of the body is 1.5 ÷ 2

times the height of the conical part, with the conical part it is connected through the pipe to the inlet of the first hydroclassifier.

The hydroclassifiers of the second and third modules are identical in design, with the inlet nozzle for the hydraulic mixture installed along the central vertical axis, passes into the diffuser inside the housing with a taper angle of 8-12 °, has a height equal to 0.8 of the height of the receiving and separation chamber and is fenced from the outside to 2/3 of its height with a cylindrical wall, which is connected to the lower end of the diffuser by an annular plate, and on top they are interconnected by a cover, in the form of a truncated cone with a taper of at least 60 °, while the ratio of the cross-sectional area Nij lower end of the funnel of the diffuser and the cylinder _pactp F: F _cyl = 1: 2.1 ÷ 2.2, the ratio of the diffuser and the height H of the cylindrical wall _raster: H _cyl = 1.6 ÷ 1.7: 1 and the ratio of the height of the cylindrical and the conical parts of the hydroclassifier N _c : H _k = 1.35: 1.

The upper output of the first hydroclassifier of the second classification module is connected by a pipeline to the input of the second hydroclassifier, the upper output of which is in turn connected by a pipeline through the shutoff valves to the input of the first hydroclassifier of the third classification module.

The hydraulic screen of the third module has twice the height of the cylindrical part, is equipped with a grid located in the cylindrical part under the entrance, and a trap hatch, and a trap in the form of an inverted truncated cone, also covered with a grid, which is connected by a pipeline passing through the lower conical part of the hydraulic screen, with a pipe connected to the input of the first hydroclassifier of the second classification module.

The upper output of the first hydroclassifier of the third classification module is connected to the input of the second hydroclassifier of the same module.

The second and third classification modules are additionally equipped with spiral hydroclassifiers for additional washing and dehydration of small fractions isolated on these modules before their output to the map. Moreover, the input of the first spiral hydroclassifier is connected by a pipeline to the upper output of the second hydroclassifier of the second classification module, and the input of the second spiral hydroclassifier is connected by a pipeline to the upper output of the second hydroclassifier of the second classification module.

On the pipeline, in front of each laminarization unit, a device for controlling the supply of working fluid and a control valve with the ability to control its operation from the control panel via the output signals of differential pressure gauges installed

with separate control, on hydroclassifiers of the second and third classification modules.

Figure 1 presents the General technological scheme of the installation; in Fig. 2 hydroclassifier of the second and third classification modules (view A-A in Fig. 1), in Fig. 3, view B-B.

The installation contains a cascade of three classification modules installed in series and hydraulically interconnected, each of which includes a receiving and separating unit, consisting of a hydraulic screen and two cylinder-conical hydroclassifiers, equipped with laminarization units at the lower outlet.

The first classification module (I) contains a hydraulic screen 1, the tangential input of which is connected to the slurry pipe 2, and two output pipes - the upper one in the form of a siphon 3 lowered into the cavity of the hydraulic screen on the central vertical axis, as a continuation of the pipe 4 with a control flap 5 and the lower one in the form of a tee 6, through which it is connected to two hydroclassifiers - hydrocyclones 7 and 8, equipped with laminarization units 9 and 10 with nozzles for supplying working fluid (water). The hydrocyclone 7 at the outlet is connected to the pipeline 4 through the control valve 11, at the lower outlet there is a laminarization unit 9, an outlet pipe, which is connected to the pipeline for outputting the target product fraction 12 to its card and an inlet pipe connected to the branch of the main water conduit 13 through the control valve 14 and flowmeter 15. The hydrocyclone 8 has a similar design, its upper output through the control valve 16 is connected to the pipe 17, at the lower output there is a laminarization unit 10, the output of which is connected to the conduit 18 for withdrawal of product fractions target on his card, and an input coupled to the input branch water main 13 through the meter 19 and the control valve 20.

The second classification module (II) contains a hydraulic screen 21, and two cylinder-conical hydroclassifiers 22 and 23. The hydraulic screen 21 is equipped with a grid 24 and an exit hatch 25 for outputting garbage to the chute 26, and its inlet is connected to the pipe 17, and an outlet pipe 27 is connected below, connecting a hydraulic screen 21 with a hydraulic classifier 22, containing, as well as the subsequent hydraulic classifiers of modules II and III inside their cylindrical receiving and separating chamber, an inlet pipe passing into a diffuser 28 (see Fig. 2), and an upper outlet connected to the pipeline 29. Diffuso p is fenced from the outside by 2/3 of its height with a cylindrical wall, which is connected to the lower end of the diffuser by an annular plate, and on top they are interconnected by a lid, in the form of a truncated cone with a taper of at least 60 °, the ratio

The cross-sectional area of the lower end of the bell of the diffuser and cylinder F _factor : F _cyl = 1: 2.1-2.2, the ratio of the height of the diffuser and the cylindrical wall is H _raster : H _cyl = 1.6-1.7: 1, the diffuser also has an angle tapers of 8-12 ° and a height equal to 0.8 of the height of the reception and separation chamber. This form of the diffuser allows you to maintain a constant cross-section of the receiving and separation chamber and create conditions for a smooth exit of the slurry into the chamber cavity without vortex formation. The ratio of the height of the receiving - dividing and classification chambers of the hydroclassifier N _c : N _k = 1.35: 1. The hydroclassifier 22 is equipped with a differential pressure gauge 30 for measuring the pressure in the cylindrical part of the hydroclassifier and in the vertical cylindrical pipe of the laminarization unit 31. The laminarization unit 31 also has an outlet pipe for outputting the target product fraction through pipeline 32 to its card and an inlet pipe connected to the branch of the main water supply 13 through a flow meter 33 and a control valve 34.

The inlet of the second hydroclassifier 23 is connected by a pipe 29 to the upper outlet of the hydroclassifier 22, and the upper outlet is connected to a pipeline 35, which has two branches, one of which is connected to the pipeline 36 through the shut-off valve 37 with the inlet of the spiral hydroclassifier 38, and through the shut-off valve 39 by the pipe 40 connected to the input of the hydroclassifier 41 of the third classification module.

The hydroclassifier 23 is also equipped with a laminarization unit 42 with an output 43 for outputting the target product fraction and with an input branch of the line 13 through a flow meter 44 and a control valve 45. The hydroclassifier 23 is also equipped with a differential pressure gauge 46.

The third classification module (III) contains a hydraulic screen 47 equipped with a cylindrical screen 48, an exit hatch 49 for removing debris to the chute 26, a flow divider 50 located on the central vertical axis and having the shape of an inverted truncated cone, the cross section of which is closed by a grid 51 and rises above the grid 48 above the level of the inlet channel of the pipeline 4 and is connected by a vertical pipeline passing through the conical part of the hydraulic screen and passing into the pipe 52, with the pipe 27 of the hydraulic screen 21. The output of the conical part of the hydraulic screen 4 7 is connected by a pipe 40 to the inlet of the hydroclassifier 41, connected by an upper outlet to the pipe 53, also equipped with a differential pressure gauge 54 and a laminarization unit 55 with an outlet pipe for product withdrawal through the pipe 56 to its card and with a branch of the water main 13 through the flow meter 57 and the control valve 58. Hydroclassifier 59, the input of which is connected to the pipe 53, and the upper outlet with the pipe 60 connected to the input of the spiral hydroclassifier 61, is equipped with -

a diphanometer 62, and in the lower part it is connected to the laminarization unit 63, which is connected to the product output line through the pipe 64 to the card and to the input branch of the main conduit 13 through a flow meter 65 and a control valve 66.

Laminating blocks 9, 10, 31, 42, 55 and 63 are of the same type and contain a receiver tank 67, a vertical pipe 68, a straightener 69 with radial plates 70 inside, dividing the pipe cross-sectional area into 4-8 equal sectors. The outputs of the spiral hydroclassifiers 38 and 61 are connected to pipelines 71 and 72, which are each directed to their own card. All cards are located on prepared sites 73, which are equipped with sewage channels 74 for collecting water, filtering it and returning it through pipeline 75 to the reservoir 76 for reuse

With valve 77 open, pump 78 fills the main water conduit 13 to supply the working fluid to all the hydroclassifiers of the installation. The control panel 79 is placed on a local shield.

Installation works as follows.

Preparation of the installation for technological operation begins in the following sequence: on the control panel 79 set the calculated values of the tasks of the volumetric flow rate of water supply for each laminarization unit with automatic correction of the flow rate from the output value of its differential pressure gauge to its control valve, open the shut-off valve 37, and close the shutter 39. Turn on the pump 78, open the valve 77, the water from the reservoir 76 is supplied through the main conduit 13 through the laminarization units 9, 10, 31, 42, 55 and 63 to the hydrocyclones 7 and 8, hydroclassifiers 22, 23, 41 and 59 from the bottom up. At the same time, slurry line 2 from the dredger (not shown in the diagram) supplies water to the hydraulic screen 1, through hydrocyclones 7 and 8, through pipelines 4 and 17, which fills the hydraulic screens 21 and 47 and enters the hydraulic classifiers 22, 23, 38, 41, 59 and 61. When all pipelines and apparatus devices are leakproof, water should leave only from the outlet pipelines 12, 18, 32, 43, 56, 64, 71 and 72. By means of the regulating flaps 5, 11 and 16, the flows are equal in pipelines 4 and 17.

After carrying out all the preparatory measures, they give a command to supply the slurry (pulp), which is prepared in the ratio T: L = (1: 8) - (1-10) and is fed through slurry pipe 2 to the tangential inlet of the hydraulic screen 1, where the slurry acquires rotational motion. Large grains move in the flow along the surface of the sieve, lose speed and spiral downward, and through the tee 6 they go to the tangential inlets of hydrocyclones 7 and 8, where, due to centrifugal forces, the fine sand mixture is separated from the coarse mixture, while the grains are wet from clay ones inclusions and organic products, as well as the separation of the sand mixture into

classes with separation of molding sands by means of oncoming water flows from bottom to top from laminarization units 9 and 10 supplied at a given speed in cylindrical chambers of hydrocyclones, where particles, for example, 0.3 mm or less, related to molding sands rise up and are carried out along pipelines 4 and 17 into the second and third modules for subsequent hydroclassification, and particles larger than 0.3 mm settle towards this flow and fall into laminarization units 9 and 10, and since the specified upward flow velocity is less than the fall velocity If larger particles are less than 0.3 mm, then through the outlet pipes through pipelines 12 and 18 they are displayed on the map (as the final product) of sands of another class. At the same time, part of the fine sand mixture (molding sand class) separated in the hydraulic screen 1, due to centrifugal force, rises along the central vertical axis and is transported through the siphon 3 through the pipe 4 to the tangential entrance of the hydraulic screen 47, and the garbage separated in the hydrocyclones 7 and 8, to prevent entry into the outlet pipelines with classified material, it is discharged to the inlets of hydraulic screens 21 and 47 due to water locks on pipelines 12 and 18 formed by a U-shaped bend raised to the level of 0.9-0.95 of the central level the horizontal axis of the tee 6, contributing to the creation of liquid backwater at this level and the removal of debris from the reception and separation chambers of hydrocyclones 7 and 8.

The sand slurry transported through pipeline 17 to the tangential inlet of the hydraulic screen 21 is washed again by centrifugal forces and passes through the grid 24, and clay inclusions, debris and organic products are deposited on the grid 24 and through the hatch 25 are discharged to the chute 26. The sand slurry transported by pipeline 4 to the tangential inlet of the hydraulic screen 47 due to centrifugal forces, is also washed, and partially, within 1/3 of the volume of sand slurry is removed from the hydraulic screen 47 through a flow divider 50 with mesh 51 through the pipeline at 52, through pipe 27 to the inlet of hydroclassifier 22, and the rest of the sandy hydraulic mixture passes through the grid 48 and through pipeline 40 enters the entrance of the hydroclassifier 41, while clay inclusions, debris, and organic products are deposited on the grid 48 and through the hatch 49 are discharged into the gutter for 26 s which are sent for recycling. The flow divider 50 is designed to equalize the volume of sand mixtures, classified on the second and third stages of the installation.

The water supply to the hydrocyclones 7 and 8 is carried out through laminarization units 9 and 10 from the main conduit 13. The water supply is controlled by flow meters 15 and 19 and manually controlled by control valves 14 and 20.

Hydroclassification of molding sands is carried out as follows: solid phase particles entering the diffuser inlet 28 of the hydroclassifier 22 from top to bottom are deposited in its cylindrical part, where they meet with the pure water flow rate calculated for the speed of this classifier from the laminarization unit 31 from bottom to top. Since the flow rate of the water flow is designed for the speed of soaking of particles of the maximum size of the selected fraction of the particle size distribution of the molding sands and larger particles in diameter than those calculated for this fraction in the sand mixture, there are no water classifiers 22 and pipe 68 of the laminarization unit 31 at the junction of the bottom the particle deposition rate is quenched (decelerated) to a value at which large particles cannot be carried up and hang at a certain height, forming a "fluidized bed", and small particles are carried upward by water flow, discharged into pipeline 29 and enter the diffuser inlet 27 of hydroclassifier 23. In the process of “boiling”, large grains of a given fraction intensively move in a horizontal plane along the entire lower cavity above pipe 68, trying to evenly distribute and fill everything free the place of the formed layer, and since the speed of the upward flow is equal to the speed of the particles of maximum particle size, the selected fraction, the layer of these particles begins to grow and increase in thickness e and its permeability to water flow is reduced and there is the possibility of settling on a surface layer of smaller particles. In this case, the water pressure under the layer increases, due to the imbalance between the mass of the layer and the pressure of the water under the layer, which begins to swell and then a pulse breakthrough of the layer occurs with a column of water with a sharp (spasmodic) decrease in the velocity of the upward flow in the adjacent zone around the water column and oscillatory the process of self-aligning the speed of this stream. This vibrational change in the water flow velocity violates the parity of particles in the “fluidized bed” and they settle equally uniformly in the form of a bound flow into the pipe 68. During a short-term violation of the speed regime of the upward water flow in the pipe 68 of the laminarization unit 31, the sedimentation rate of the set large particles of the layer has time exceed the speed of the upward flow restored to a predetermined value, they settle to the bottom of the tank - receiver 67 of the laminarization unit 31, and then are transferred to the map via pipeline 32 as the final uct, and particles of a smaller size than specified during deposition falling into an upward flow restored to a predetermined value do not have time to develop their deposition rate greater than the upward flow velocity and are carried upstream of pipe 68 into a cylindrical receiving and separating chamber of hydroclassifier 22 and then through pipeline 29 and to the diffuser input 27 of the hydroclassifier 23

to highlight the next desired fraction. Since hydroclassifiers 22, 23, 41 and 59 and laminarization blocks 9, 10, 31, 42, 55 and 63 are identical in design and operation principle, the processes described in hydroclassifier 22 proceed similarly in hydroclassifiers 23, 41 and 59. Therefore the classified (target) fraction from the hydroclassifier 23 is output through the pipeline 43 to the card as the final product, and smaller grains, as the next fraction, are sent along the granulometric row through the pipeline 35 with the shutter 37 open and through the pipeline 36 to the input of the spiral hydroclassifier 3 8, where all the remaining sand mixture is washed again, dehydrated, and sent via pipeline 71 to the map as the final product.

Particles of the solid phase, coming in the form of a hydraulic slurry from a hydraulic screen 47 through a pipe 40 into the diffuser inlet 27 of the hydroclassifier 41 from top to bottom, are also deposited in the cylinder-conical chamber, where they meet with the water flow calculated for this classifier, calculated for the speed of particles of the maximum particle size of the selected particle size range class of molding sands, are classified similarly to the stages described above, and are output through the laminarization unit 55 via pipeline 56 to the map as the final product, and chalk Grains are removed from hydroclassifier 41 via pipeline 53 to the diffuser inlet of hydroclassifier 59 from top to bottom, where they are classified according to the maximum grain size of the selected fraction of the particle size range of the molded sand class, the selected particles are output through the laminarization unit 63 through pipeline 64 to the card, as the final product, and the particles less than a given fraction are removed by a high-speed stream from the hydroclassifier 59 through the pipeline 60 to the inlet of the spiral hydroclassifier 61, where they are additionally washed, dehydrated They are also displayed on the map 72 as a final product.

The hydroclassifier 41 with the open damper 39 on the pipeline 35 and the closed damper 37 on the pipeline 36 allows to classify the removed grains on module III in addition to the sand mixture from the hydraulic screen 47.

At the initial density of the slurry fed from the dredger with the ratio T: L = (1: 8) ÷ (1-10) and the sandy classified mixture is withdrawn from module I, the ratio T: W varies in the range (1:10) ÷ (1-12 ) All changes in the density of the mixture, as well as when changing the performance of supplying the hydraulic mixture to the installation, are converted by pressure gauges on each hydroclassifier into the pressure drop between the pressure in the cylindrical chamber of the hydroclassifiers and the pressure of the water supply from bottom to top in pipe 68, and the speed flow of each laminarization unit is adjusted based on the results of the change in the differential. All cards of the finished product are located on prepared

sites 73 with bypass channels 74, where the water is filtered, clarified and returned through the pipeline 75 to the reservoir 76 for reuse.

At the proposed installation, it is possible to obtain up to eight different fractions of high uniformity of sand of different classes.

Claims (11)

1. Installation for hydroclassification of polydisperse granular materials, containing a cascade of three classification modules sequentially installed and hydraulically interconnected, each of which includes a receiving and separating unit, which is a hydraulic screen with a cylindrical shape with a tangential inlet in the upper cylindrical part for supplying the hydraulic mixture and a lower outlet in the conical part, and two hydroclassifiers, including a housing consisting of a cylindrical receiving and separating and conical class fiction chambers, an inlet pipe for hydraulic mixture, an outlet pipe for outputting a fine fraction installed in the receiving and separation chamber, and a pipe for outputting a target fraction installed in the lower part of the classification chamber, all hydroclassifiers are equipped with a laminarization unit, which is a construction in the form of a conditional tee, consisting of a receiver tank, into which at 1/4 of its height along the central vertical axis the first part of the tee is lowered - a cylindrical vertical pipe, which is combined with the bottom by the hydroclassifier output, the second part of the tee - the inlet pipe with the jet straightener is set at 2/3 of the height of the receiver tank, is designed to enter the working fluid through the receiver tank into the conical part of the hydroclassifier, and the third part of the tee is the outlet pipe installed diametrically to the jet straightener at 1 / 3 heights of the tank-receiver. 2. The installation according to claim 1, characterized in that the ratio of the cross-sectional area of the pipes of the laminarization unit F _under : F _in : F _out = 1.0: 0.18: 0.08, where F _under - the cross-sectional area of a cylindrical vertical pipe; F _I - the cross-sectional area of the inlet pipe; F _o - the cross-sectional area of the outlet pipe. 3. Installation according to claim 1 or 2, characterized in that the straightener is a nozzle with radial plates placed inside, dividing the cross-sectional area of the nozzle into 4 ÷ 8 equal sectors. 4. Installation according to claim 1 or 2, characterized in that the hydroclassifiers of the second and third modules are identical in design, and the inlet pipe for the hydraulic mixture is installed along the central vertical axis, passes into the diffuser with a taper angle of 8 ÷ 12 ° inside the body, has a height equal to 0.8 height of the reception and separation chamber and is fenced from the outside by 2/3 of its height with a cylindrical wall, which is connected to the lower end of the diffuser by an annular plate, and on top they are interconnected by a cover, in the form of a truncated cone with a taper at least 60 °, while the ratio of the cross-sectional area of the lower end of the diffuser bell and cylinder F _raster : F _cyl = 1: 2.1 ÷ 2.2, the ratio of the height of the diffuser and cylindrical wall H _raster : N _cyl = 1.6 ÷ 1, 7: 1, and the ratio of the height of the cylindrical and conical parts of the hydroclassifier N _c : N _k = 1.35: 1. 5. Installation according to claim 1 or 2, characterized in that the hydraulic screen of the first classification module contains an upper outlet pipe for removing small fractions in the form of a siphon, which is lowered into the body of the hydraulic screen by 1/3 of its height along its central vertical axis, and the lower outlet through a tee connected to the upper tangential inlets of two hydroclassifiers, which are hydrocyclones, the upper exits of the hydro screen and the first hydrocyclone are connected by a pipe through control valves to the hydro screen input of the third class module pecifications and the upper outlet of the second hydrocyclone is connected via a conduit with a regulating valve tangential entry Hydro second classification module. 6. Installation according to claim 1 or 2, characterized in that the hydraulic screen of the second classification module is equipped with a grid located in the conical part and a hatch for removing debris, the height of the cylindrical part is 1.5 ÷ 2 times the height of the conical part, and it is the conical part through a pipe connected to the inlet of the first hydroclassifier. 7. Installation of claim 1 or 2, characterized in that the upper output of the first hydroclassifier of the second classification module is connected by a pipeline to the input of the second hydroclassifier, the upper output of which, in turn, is connected by a pipe through the shut-off valve to the input of the first hydroclassifier of the third classification module. 8. Installation according to claim 1 or 2, characterized in that the hydraulic screen of the third classification module has twice the height of the cylindrical part with respect to the conical one, equipped with a grid located in the cylindrical part under the entrance, and a hatch for removing garbage, and above the grid along the central a vertical axis has a trap in the form of an inverted truncated cone, also covered with a grid, which is connected by a pipe passing through the lower conical part of the hydraulic screen to a pipe connected to the inlet of the first hydroclassifier of the second mode for classification, and the output of the first hydroclassifier of the third classification module is connected to the input of the second hydroclassifier of the same module. 9. Installation according to claim 1 or 2, characterized in that the pipelines connected to the outlet pipes of the laminarization blocks of the first classification module are made in the form of hydraulic locks, by u-shaped bending and raising the upper point by 0.9 ÷ 0.95 of the block connection level laminarization with tangential inlets of hydrocyclones. 10. Installation according to claim 1 or 2, characterized in that it further includes two spiral hydroclassifiers, the input of the first spiral hydroclassifier connected by a pipeline to the upper outlet of the second hydroclassifier of the second classification module, and the input of the second spiral hydroclassifier connected by a pipeline to the upper output of the second spiral hydroclassifier of the second classification module. 11. Installation according to claim 1, characterized in that on the pipeline in front of each laminarization unit there is a device for controlling the supply of working fluid and a control valve with the ability to control its operation from the control panel by means of control signals of differential pressure gauges installed on each hydroclassifier of the second and third classification modules with separate control.