RU2495722C2 - Method of sludge tank coal slimes concentration and concentration table to this end - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to recovery of minerals processing wastes, particularly, recovery of sludge tank coal slimes at concentration plants of coal an chemical recovery plants. Proposed method comprises feed of pre-processed pulp of slurry coal and flushing water to concentration table deck working surface, division of coal-bearing fractions and slurry coal at deck working surface to be discharged therefrom. Said separation is performed at feeding additional flushing water to deck working surface in continuous jets via openings made in said deck between its flutes, flow rate of said additional water making 5-20% of the amount of main water. Proposed concentration table comprises frame, deck with flutes made at its working surface, flexible supports to mount the deck at the frame, vibratory drive connected with deck, deck inclination control mechanisms, pulp and flushing water feed means, and means to discharge coal bearing fractions and slurry coal from deck surface. Additional flushing water feed channels are made parallel with deck flutes connected via opening made between deck flutes with deck working surface.

EFFECT: higher yield of coal bearing fractions and coal concentrate, higher efficiency of concentration.

4 cl, 7 dwg, 1 tbl

Description

The invention relates to a technology for the disposal of mineral processing waste, in particular the disposal of coal sludge sludge collectors, which are formed at the processing plants of the coal and coke industry as technological waste.

As a result of long and intensive coal mining, for example, in Ukraine, 74 sludge collectors of 62 processing plants contain 62.5 million m ^{3 of} coal sludge - waste from coal preparation technology, which occupy an area of more than 1,500 hectares. There is an urgent need to recycle these wastes in order to isolate useful raw materials and to restore land (http://waste.com.ua/cooperation/2005/theses/matsak.html). In some regions, so much industrial waste has been accumulated that the issue of their disposal has become a serious economic and environmental problem. For example, in the Donetsk region of Ukraine there are more than 170 thousand tons of balance sludge with an ash content of 45%, off-balance sludge of the first category - more than 13.5 million tons with an ash content of 60% and off-balance sludge of the second category - more than 14.5 million tons with an ash content of 70-75 %, (http://www.nbuv.gov.ua/portal/natural/Geotm/2009_82/15.pdf).

With the development of the mechanization of coal mining, there has been a tendency to increase the yield of small classes of coal. For example, switching to a harvesting recess leads to an increase in the output of the class 0-1 mm to 30-35% instead of 10-15% that were previously acceptable. The yield of fine coal fractions significantly increases with a multi-stage system of transporting rock mass to the surface. The methods of hydraulic mining and transportation of coal, developing recently, lead to additional grinding of coal in pipelines, coal pumps, etc.

The problem of processing coal sludge is the enrichment of coal sludge with the release of fine fractions of coal, which has not been fully resolved to date. Known technologies for coal sludge enrichment do not provide an effective separation of the carbon-containing fraction from small classes of coal. The complexity of the enrichment of coal sludge from sludge collectors is mainly determined by the high ash content of the initial product, the low content of granular particles, since the solid phase of coal sludge is represented by particles less than 75 μm or more, by sharp fluctuations in the fractional and particle size distribution of sludge collectors.

To enrich coal sludge, flotation methods are widely used using various flotation reagents and specialized equipment. When flotation of coal sludge, as a rule, schemes are used that provide for the production of two products - coal concentrates and tailings (waste).

As an example of flotation enrichment of coal sludge, one can cite a method of enrichment of coal sludge, known according to the patent of the Russian Federation No. 2223828, IPC ⁷ B03D 1/02, filing date 04.04.2002. The invention relates to methods for the selective concentration and separation of fine coal particles from water-coal suspensions and can be used to enrich coal sludge in processing plants, processing slurry of hydraulic dumps, and the regeneration of sludge water from enterprises.

The claimed method includes feeding an oil reagent and a foaming agent into a water-coal suspension, selective oil agglomeration of coal particles by continuously feeding dispersed air into the suspension, separation of enriched products by flotation, while selective oil agglomeration is carried out in the agglomeration chamber while the suspension is stirred for 2-3 minutes with a rotating mixer at a peripheral speed of rotation of 6 m / s, the oil reagent and foaming agent are introduced into the suspension at a weight ratio of reaction comrade from 5: 1 to 40: 1 and a total amount of 0.1-0.25% by weight of dry coal, and the separation by flotation product selection is performed in the flotation cell at the end of the stirring suspension. As a result, at a cost of 0.18% oil reagent and a blowing agent 0.02% by weight of dry coal, coal concentrate is obtained with a yield of 87.3%, an ash content of 6.5% and a waste ash content of 61.6%. The method is implemented using special flotation equipment and flotation reagents.

The possibilities of flotation enrichment of fine coal sludge are limited by the low selectivity of separation of particles of the class -0.05 mm, the need to use capital facilities, special flotation equipment and expensive flotation reagents, which significantly increases capital and operating costs, as well as the pollution of flavored products with flotation reagents, often carcinogenic.

Recently, special attention has been paid to gravity methods for coal sludge enrichment, which allow implementing the enrichment technology using simple, highly productive and inexpensive equipment with minimal energy consumption compared to other enrichment processes. Gravity dressing is used to process a number of minerals, including coal sludge sludge collectors.

Gravitational enrichment processes are understood to mean processes in which the separation of mineral particles of different density, size or shape is due to the difference in the nature and speed of their movement in the fluid under the action of gravity and resistance to their movement. Gravity processes include, for example, jigging, enrichment at locks, gutters, screw separators, concentration tables. As the environment in which gravitational enrichment is carried out, water is most often used. Under these conditions, the particles of the material are affected by the gravitational force, hydrodynamic forces, forces arising from the collision of particles and their friction, both between themselves and about the bottom or walls of the apparatus in which enrichment is carried out. When using water as a medium in which gravitational enrichment is carried out, the process of particle separation is called hydraulic. In this case, the interaction forces between the particles are small in comparison with the hydrodynamic forces.

Given the features of the proposed method and means of enrichment of coal sludge sludge collectors, of particular interest are the technology of gravitational enrichment of coal sludge using concentration tables.

Gravity enrichment on a concentration table is a process of separating solid particles by density and particle size in a pulp layer flowing along a flat inclined deck, which performs reciprocating (oscillatory) movement in a horizontal plane. During the stay of the material on the deck of the concentration table, particles are transported in the longitudinal and transverse directions in accordance with their density and particle size under the influence of the deck vibrations, turbulent pulsations (excitations) of the pulp stream, as well as jets on the interface between the pulp and air. The exfoliated material is continuously amenable to the effect of a flushing water stream. When the enriched material leaves the table edge in the first zones, the smallest and lightest grains (carbon-containing fractions) are located; in subsequent zones, the density of the material increases (rock fractions).

It should be noted that, despite the widespread use worldwide of gravitational methods of enriching many minerals on concentration tables, today there are no mathematical models that comprehensively and adequately describe the processes of fraction separation. Obviously, the use of various equipment, as well as unsuccessful attempts to practically implement the technology of gravitational enrichment of coal sludge on concentration tables, result from a lack of understanding of the processes that occur.

Currently, the technology of gravity enrichment of coal sludge on concentration tables provides for the supply of pre-prepared pulp of coal sludge and washing water to the working surface of the deck of the concentration table, separation of coal-containing fractions and coal sludge on the working surface of the deck, and subsequent separate unloading of coal-containing fractions and rocks through concentration pockets the table. This technology is described in many sources of information (for example, "Technology for processing coal slurries using a support type concentration table manufactured by the Trud plant", Novosibirsk (http://sibecotechnika.narod.ru/>index1.html), " Enrichment on vibration tables, basic principles "(<http://www.masters.donntu.edu.ua/2007/fema/svetlichnaya/library/spravochnik> .htm)," Gravity mineral processing "(<http: // www.enc-dic.com/>encgeolog/Gravitacionnoe-Obogaschenie-1643.html), “Gravity Enrichment” (http://bse.sci-lib.com/article012653.html), and others). That is, the technology and means of its implementation are widely known.

Thus, as a prototype of the proposed method, a well-known method of gravitational enrichment of coal sludge using concentration tables is adopted, which includes the supply of pre-prepared pulp of coal sludge and washing water to the working surface of the deck of the concentration table, separation on the working surface of the deck of carbon-containing fractions and coal sludge rock followed by separate unloading of carbon-containing fractions and rocks from the concentration table.

Common features of the prototype and the proposed method are: a method of gravitational enrichment of coal sludge from sludge collectors, which includes supplying pre-prepared pulp of coal sludge and washing water to the working surface of the deck of the concentration table, separation of coal-containing fractions and coal sludge on the working surface of the deck, followed by separate unloading of coal-containing fractions and rocks from the concentration table.

Concentration tables are widely known that are used in the technologies of gravitational enrichment of mineral raw materials, including those for gravitational enrichment of coal sludge from sludge collectors, which are classified according to technological characteristics (sand for ore dressing with a fineness of -3 - + 0.2 mm, slurry for dressing of initial products fineness of -0.2 mm), as well as for structural features (tables with a rectangular deck, tables with a diagonal deck, supporting tables, tables of hanging execution, etc.).

Considering the features of the claimed concentration table, the SKO-15 concentration two-deck support table manufactured by the Trud plant, Novosibirsk, the Russian Federation (Donchenko A.S., Donchenko V.A. "Reference manual for the ore-dressing factory", was selected as a prototype, Moscow, "Nedra", 1975, p.173), which today is widely used for wet dressing of various ores and coals ("Technology for processing coal sludge using a support-type concentration table produced by the Trud plant, Novosibirsk" (http: //sibecotechnika.narod.ru/>index1.html)).

The SKO-15 concentration table includes a frame on which two decks (upper and lower) are mounted elastically using rubber shock absorbers, which is connected to a vibrator. On the working (upper) surfaces of the decks, flutes are made with the formation of inter-flange zones. Decks are mounted on the frame on three supports (one front support on the side of the vibrator and two rear support on the opposite side). The supports are equipped with screw mechanisms for regulating the longitudinal and transverse angles of inclination of the decks. In the upper part of the decks, means for supplying pulp of the enriched material and washing water to the working surfaces of the decks are installed. In the lower part of the deck there are fixed troughs for separate unloading of carbon-containing fractions (coal concentrate) and rock from the working surfaces of the decks of the concentration table.

Before work, set the preset angles of the longitudinal and transverse tilt of the decks with the help of screw mechanisms mounted on the supports of the decks. Elastically fixed decks are vibrodrive in oscillatory motion with a given frequency, amplitude and other parameters of the oscillatory motion. On the working surface of the deck serves pre-prepared pulp of coal sludge with a given solid phase content and its size class and wash water. On the deck of the concentration table, particles are transported in the longitudinal and transverse directions in accordance with their density and size under the influence of deck vibrations, turbulent pulsations (excitations) of the pulp stream, and also jets on the interface between the pulp and air. As a result, particles move along the diagonal of the deck. The distribution of particles along the height of the stream and the working surface of the deck is determined by their size, density and shape as a result of the compatible action of these forces. Rinsing water carries these grains from the table deck to the discharge chute. At the same time, the thinnest and lightest grains of coal sludge (carbon-containing fractions) enter the first zone of the discharge chute, and high density fractions (rock fractions) enter the subsequent zones of the discharge chute. Thus, on the deck of the concentration table, a fan of separation of material particles by density and particle size is created, which provides the possibility of separate unloading of carbon-containing fractions and coal sludge from the deck of the concentration table.

Common features of the prototype and the proposed concentration table are: a concentration table, including a frame, a deck with flutes on its working surface, elastic supports with which the deck is mounted on the frame, a vibrator connected to the deck, and mechanisms for adjusting the transverse and longitudinal angles of the deck, installed on elastic supports, means for supplying pulp and washing water to the working surface of the deck, means for separate unloading of carbon-containing fractions and coal sludge from the working surface of the deck.

In the above-described method of gravitational enrichment of coal sludge and a concentration table for implementing the method, which are selected as prototypes, there is a factor limiting the efficiency of enrichment of pulp of coal sludge. This is explained as follows.

The nature of the movement of pulp of coal sludge together with washing water along the working surface of the deck of the concentration table is shown in Fig. 1.

As a result of flow swirls in the inter-flange zone of the concentration table deck in areas adjacent to the flutes, stagnant tubular circulation zones (vortices) are formed, inside which particles with the highest density (rock) can capture and hold light thin coal particles. The reason for this is the vortex velocity field in the cross section, favorable for this phenomenon. The circulation vortices are especially developed in areas adjacent to the lower located riffle. This phenomenon leads to a decrease in the degree of extraction of carbon-containing fractions from the pulp of coal sludge, a decrease in the yield of coal concentrate, a decrease in the ash content of the waste, that is, to a decrease in the efficiency of processing coal sludge.

The basis of the invention is the task of improving the method of gravitational enrichment of coal sludge of sludge collectors and a concentration table as a means of implementing the method, in which due to technological and design features, an increase in the degree of extraction of carbon-containing fractions from the pulp of coal sludge, increase the yield of coal concentrate and the efficiency of processing coal slurry are provided.

The problem is solved in that in the method of gravitational enrichment of coal sludge sludge collectors, including the supply of pre-prepared pulp of coal sludge and wash water to the working surface of the deck of the concentration table, the separation on the working surface of the deck of carbon-containing fractions and rocks of coal sludge with subsequent separate unloading of coal-containing fractions and rocks from the concentration table, in accordance with the invention, the separation of carbon-containing fractions and coal sludge rock is performed feeding the working surface concentration deck section further continuous washing water jets through the openings formed in the deck between its riffles at a flow rate of additional wash water within 5-20% of the main flow of the wash water.

These signs are essential features of the proposed method of gravitational enrichment of coal sludge sludge collectors.

The problem is also solved by the fact that in the concentration table, as a means of implementing the method, including a frame, a deck with flutes on its working surface, elastic supports with which the deck is mounted on the frame, a vibrator connected to the deck, the transverse and longitudinal adjustment mechanisms deck tilt angles mounted on elastic supports, means for supplying pulp and washing water to the deck working surface, means for separate unloading of carbon-containing fractions and coal sludge rock from the deck working surface, in tvetstvii to the invention, in deck parallel corrugated deck made more wash water feed channels through openings formed in the deck between its riffles, connected with a working deck surface.

These signs are essential features of the proposed concentration table as a means of implementing a method of enrichment of coal sludge sludge collectors.

It is advisable to open the holes for supplying additional washing water in the area of the inter-flush zone adjacent to the lower riff, and place the channels for supplying additional washing water on the deck through 2-5 riffles of the deck.

The essential features of the invention are in a causal relationship with the achieved result.

So, the distinctive features of the proposed method of gravitational enrichment of coal sludge sludge collectors (the separation of coal fractions and coal sludge rocks is performed by feeding additional flushing water to the working surface of the deck of the concentration table with continuous jets through openings made in the deck between its flutes, with the flow of additional flushing water within 5-20% of the flow rate of the main wash water), together with the essential features common with the prototype, provide an increase in step extracting audio carbonaceous coal fraction from a pulp slurry to increase the yield of coal concentrate and processing efficiency of the coal slurry.

Distinctive features of the concentration table, as a means of implementing the method of gravitational enrichment of coal sludge sludge collectors (in the deck parallel to the deck riffles, channels for supplying additional washing water are made, which are connected to the working surface of the deck through the holes made in the deck between its riffles) in combination with essential features, common with the prototype, provide an increase in the degree of extraction of carbon-containing fractions from the pulp of coal sludge, increase the yield of coal concentrate and efficiently coal sludge processing industry.

This is explained by the following. The supply of additional flushing water with continuous jets through the holes made in the deck of the concentration table between the flutes of the deck, with the flow of additional flushing water within 5-20% of the flow rate of the main flushing water, changes the coal slurry pulp movement together with the flushing water along the working surface of the concentration table deck . Figure 2 shows the nature of the movement of the pulp when applying additional flushing water in the specified way.

The supply of additional flushing water with continuous jets through the holes made in the deck of the concentration table between the flutes of the deck with the flow of additional flushing water within 5-20% of the flow rate of the main flushing water eliminates stagnant areas in the inter-flange zones, especially in areas adjacent to the lower flute , provides intensive separation of the solid phase of the pulp in density and size, the removal of light and fine particles of carbon-containing fractions in the upper layers of the stream, their washing rinsing with water and thereby increase the degree of extraction of carbon-containing fractions, increase the yield of coal concentrate and the efficiency of processing coal sludge.

After the thin and light particles of carbon-containing fractions are carried out into the upper layers of the pulp stream and washed off with wash water in the next inter-flange zone, the probability of their getting into the circulation vortex inside the inter-flute zone without supplying additional wash water is sharply reduced. Therefore, additional flushing water is supplied to the inter-zone zones in increments of 2 to 5 riffles. Additional flushing water is supplied to several interflat zones to completely remove fine and light particles from the circulation vortices and reduce losses of carbon-containing fractions with waste. The step of supplying additional washing water depends on many factors, the main of which are the particle size and fractional compositions of the solid phase of the initial sludge. The step of supplying additional washing water (from 2 to 5 flutes) was determined experimentally and is optimal for the efficient separation of coal sludge fractions.

The consumption of additional flushing water also depends on many factors, the main of which is the particle size distribution of coal sludge. The consumption of additional washing water in the range of 5-20% was determined experimentally and is optimal for the efficient separation of coal sludge fractions.

The method of gravitational enrichment of coal sludge sludge collectors and a concentration table, as a means of implementing the noted method, which are claimed to meet the requirements of the unity of the invention, since one of them (concentration table) is designed to implement another (method of gravitational enrichment of coal sludge sludge collectors) and form the only inventive concept .

The following is a description of the method of gravitational enrichment of coal sludge sludge collectors and a concentration table for implementing the method, as well as examples of their practical use with reference to the drawings, which show:

Figure 1 - A method of enrichment of coal sludge sludge collectors and a concentration table for implementing the method, the nature of the movement of the pulp without the supply of additional washing water.

Figure 2 - A method of enriching coal sludge sludge collectors and a concentration table for implementing the method, the nature of the movement of the pulp with the supply of additional flushing water.

Figure 3 - Method for the enrichment of coal sludge sludge collectors and a concentration table for implementing the method, a schematic diagram of the method.

Figure 4 - Method for the enrichment of coal sludge sludge collectors and a concentration table for implementing the method, a concentration table.

Figure 5 - Method for the enrichment of coal sludge sludge collectors and a concentration table for implementing the method, the deck of the concentration table.

6 - A method of enrichment of coal sludge sludge collectors and a concentration table for implementing the method, node I in figure 5.

7 - A method of enrichment of coal sludge sludge collectors and a concentration table for implementing the method, section aa in Fig.6.

The inventive method of enrichment of coal sludge sludge collectors includes feeding to the working surface of the deck of the concentration table pre-prepared pulp of coal sludge and main washing water, as well as supplying additional washing water with continuous jets through the holes that are made in the deck between its flutes, with the flow of additional washing water within 5-20% of the main wash water consumption, separation of coal-containing fractions and coal sludge rock on the working surface of the deck, followed by separate unloading of carbon-containing fractions and rocks from the concentration table. Schematic diagram of the method shown in Fig.3.

The preparation of the pulp with a given class size and solid content is carried out according to known technologies using known equipment (vibrating screens, hydrocyclones, mixers and others).

The separation on the working surface of the deck of the concentration table of coal-containing fractions and coal slurry rocks in density and size is carried out in a pulp layer flowing along a flat inclined deck, which oscillates in a horizontal plane. Under the influence of deck vibrations, turbulent pulsations (excitations) of the pulp stream, as well as jets on the interface between the pulp and the air, solid pulp particles move along the diagonal of the deck. At the same time, the thinnest grains of high density are located in the lower layers of the flow, above them are larger than the same density in a mixture with small grains of lower density, and even higher are large and small grains of low density. The supply of additional flushing water with continuous jets through openings made in the deck of the concentration table between the flutes of the deck, at the indicated flow rate, eliminates stagnant areas in the inter-flange zones. When the enriched material leaves the table in the first zones, the finest and lightest grains (carbon-containing fractions) are unloaded, in the subsequent zones, denser fractions (rock fractions) are unloaded. This ensures separate unloading of carbon-containing fractions (coal concentrate) and rock fractions (waste).

The obtained coal concentrate, as a rule, is subjected to further processing to ensure the specified consumer characteristics of the final product by dehydrating the coal concentrate with possible options for granulating or briquetting using known technologies.

The concentration table for implementing the described method (Figs. 4, 5, 6, 7) includes a frame 1, on which two decks 2 (upper and lower) are installed elastically (using rubber shock absorbers), which are connected to the vibration drive 3. On the workers (upper ) the surfaces of deck 2 are made of flutes 4 with the formation of inter-flange zones 5. Decks 2 are mounted on the frame on three supports 6 (one front support 6 from the side of the vibrator 3 and two rear supports 6 from the opposite side). The supports 6 are equipped with screw mechanisms 7 for regulating the longitudinal and transverse inclination angles of deck 2. In the upper part of deck 2, means for supplying enriched material in the form of receiving trays 8 and washing water in the form of trays 9 to the working surfaces of the deck 2 are installed. In the lower part of deck 2, means are fixed separate unloading from the working surfaces of Dec 2 of the concentration table of coal-containing fractions (coal concentrate) in the form of trays 10 and rock in the form of trays 11. Trays 10, 11 of unloading coal concentrate and rock are made with discharge pipes ubam 12. In decks 2, channels 13 for supplying additional washing water are made parallel to the flutes on Dec 4; they are connected through the holes 14 made in decks 2 between the flutes 4 to the working surfaces of deck 2. The holes 14 for supplying additional washing water are made in the area of the inter-flange zone 5, which is adjacent to the lower located riffle 4. Channels 13 for supplying additional flushing water are located on the deck with a step through 2-5 riffles 4 of deck 2.

Before starting work, set the preset angles of the longitudinal and transverse tilt of deck 2 using screw mechanisms 7 mounted on the supports of December 6, 2. Elastically fixed decks 2 are driven by vibration drive 3 into vibrational motion with a given frequency, amplitude and other parameters of vibrational motion. On the working surface of deck 2 serves pre-prepared pulp of coal sludge with a given solids content and its size class and wash water. Wash water costs are determined primarily by coal slurry pulp characteristics. On decks 2 of the concentration table, solid particles of the pulp are transported in the longitudinal and transverse directions in accordance with their density and particle size under the influence of vibrations of the deck 2, turbulent pulsations (excitations) of the pulp stream, as well as jets on the interface between the pulp and air. As a result, the solid particles of the pulp move along the diagonal of the deck 2. The distribution of particles along the height of the stream and on the working surface of the deck 2 is determined by their size, density and shape as a result of the compatible action of these forces. At the same time, the thinnest grains of high density are located in the lower layers of the pulp stream, above them are larger than the same density in a mixture with small grains of lower density, and even higher are large and small grains of low density. Rinsing water carries these grains from deck 2 to the discharge chute. At the same time, the thinnest and lightest grains of coal sludge (carbon-containing fractions) enter the first discharge chutes, and the high density fractions (rock fractions) enter the subsequent discharge chutes. Thus, the possibility of separate unloading of carbon-containing fractions and coal sludge from deck 2 of the concentration table is provided.

The following are in tabular form examples of practical implementation of the proposed method and concentration table for implementing the method.

Table Name of parameters Example 1 Example 2 Example 3 Source Pulp Parameters The solids content in the pulp, g / l pulp 250 230 270 The size class of the solid phase in the pulp, mm 0.1-3.0 0.1-3.0 0.1-3.0 Slurry ash content in pulp,% 48.0 50,5 46,4 Pulp fortification process parameters The consumption of additional flushing water,% of the flow rate of the main flushing water 15.0 15.0 20,0 Coal Concentrate Parameters The solids content in the coal concentrate, g / l 230 230 220 The size class of the solid phase in coal concentrate, mm 0.1-3.0 0.1-3.0 0.1-3.0 Ash content of coal concentrate,% 20.8 20.3 12.9 Ash content,% 81.5 82.3 84.2 The degree of extraction of carbon-containing fractions,% 64.5 65.6 73.3

The table shows that the proposed method of enrichment of coal sludge sludge collectors and a concentration table for implementing the method provide an increase in the degree of extraction of carbon-containing fractions from coal sludge (the degree of extraction of carbon-containing fractions according to the prototype is 50.2-58.7%), and, therefore, increase the efficiency processing of coal sludge.

Claims (4)

1. A method of enriching coal sludge from sludge collectors, including feeding pre-prepared pulp of coal sludge and washing water to the working surface of the deck of the concentration table, separation on the working surface of the deck of carbon-containing fractions and rocks of coal sludge, followed by separate unloading of carbon-containing fractions and rocks from the deck of the concentration table, characterized the fact that the separation of carbon-containing fractions and rocks of coal sludge is carried out with the filing on the working surface of the deck of the concentration of and additional wash water continuous jets through the openings formed in the deck between its riffles at a flow rate of additional wash water within 5-20% of the main flow of the wash water. 2. A concentration table, including a frame, a deck with corrugations on its working surface, elastic supports with which the deck is mounted on the frame, a vibrator connected to the deck, transverse and longitudinal deck tilt adjustment mechanisms mounted on the elastic supports, pulp feeding means and washing water to the working surface of the deck, means for separate unloading of carbon-containing fractions and coal sludge from the working surface of the deck, characterized in that in the deck parallel to the grooves of the deck are made channels for supplying up to olnitelnoy wash water, which, through openings formed in the deck between its riffles, connected with a working deck surface. 3. The concentration table according to claim 2, characterized in that the holes for supplying additional washing water are made in the area of the inter-flange zone adjacent to the lower flute. 4. The concentration table according to claim 2, characterized in that the channels for supplying additional flushing water are located on the deck in increments of 2-5 deck riffles.

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