EP0316450A1 - Method of obtaining coke - Google Patents

Abstract

A method of obtaining coke includes thermal treatment of disintegrated coal charge, its coking and cooling down of the obtained coke. The thermal treatment of the coal charge is effected by mixing it with the coke at a temperature of 600-1000 DEG C at a weight ratio between the charge and the coke equal to 1.3-2.6:1 and in direct-flow regime, so that the coke is cooled down to a temperature of 150-250 DEG C and the charge is heated to 120-240 DEG C. After termination of the heat exchange process the coal-coke mixture is separated into the cooled coke and the charge. The heated charge is then used for coking.

Description

Technical field

The present invention relates to coke chemical production and, more particularly, relates to a process for producing coke which is used in the metallurgical industry.

Underlying state of the art

A process for coke extraction is known which is used to this day and consists in the coking of the comminuted coal with an initial moisture content of 8 to 10% and the cooling of the coke obtained in the wet extinguishing process.

With sufficient stocks of good coking coal and with no energy deficiency, this conventional coke extraction process has taken into account the requirements of the coke chemical industry.

The depletion of the geological reserves of good coking coal made it necessary to search for and develop new technologies that would allow coke to be obtained under the conditions of deterioration in the raw material base, the quality characteristics of which would meet the demands of metallurgical production.

The question of the utilization of heat that is given off when coke is cooled down has been drawing the attention of coke chemists for over 40 years, since around 350000-370000 kcal of heat per ton of coke is carried off into the atmosphere with water vapors , which is about 50% of the total heat required for the coking process. ("Manual of the Kokschemikers", edited by A.K. Shelkov, Vol. 2, 1965, p.173).

The most advanced technology that allows coke quality to improve under the conditions of deteriorating coking raw material base, to increase the performance of coke oven batteries and to reduce energy consumption, is a technology of coke extraction that involves the heat treatment of the input coal before coking , which includes the coking of the heated coal and the cooling of the coke in the dry quenching process.

The essence of this process is that the comminuted coal with an initial moisture content of 8 to 10% in reactors of various types (dryer tube, fluidized bed, berchar dryer, heat exchange drum, etc.) in the flow of a gaseous heat carrier in a separate unit (furnace ) is generated, dried and heated, the heated coal is charged at a temperature of 120 to 150 ° C in the chambers of a coke oven battery, where the coking process takes place. (Magazine "Glückauf", No. 6, 1973. Essen, FRG, Rode B., Beck K.-G., "Fräkarbon - a new process for the use of preheated coking coal", pp. 28 to 39; magazine "Koks und Chemistry ", No. 9, 1975, Moscow, USSR, Babanin BI and others" Mastery of the deep drying of the coal in a large-scale pilot plant ", p. 9-12).

The coke produced in the coke chambers with a temperature of 1000 to 1050 ° C is fed into the chamber of a dry fire extinguishing system, in which the heat of the coke is used in a waste heat boiler with the help of an inert medium gas. The steam generated in this heat boiler is used for energy purposes. ("Kokschemiker's Handbook", edited by A.K. Shelkov, Vol. 2, 1965, pp. 173 to 175).

Such a coke extraction process has shown considerable effectiveness. Thanks to the heat treatment of the crushed coal, its bulk density is increased. This in turn led to an increase in the performance of the coke oven batteries and the creation of the possibility of increasing the share in the uses of the low-baking coals and, in the end, expanding the raw material base for coking.

In addition, the coking conditions are improved through the use of the thermally treated coal, which contributes to an improvement in the uniformity of the grain composition of the coke produced and to an increase in its mechanical strength. The cooling of the coke with gas with the subsequent utilization of heat makes it possible to use secondary energy sources of the coke.

Keeping the coke isothermally at a temperature of 1000 ° C in the upper part of the bunker (prechamber) of the dry extinguishing system leads to a stabilization of the coke properties, and a slow cooling (without thermal shock, as is the case with wet cooling) improves the Strength properties of the coke and ensures the uniformity of its grain composition.

However, a number of problems emerged in the practical implementation of such a technology.

During the heat treatment of the comminuted coal with gaseous heat transfer medium, part of the coal in the form of a fine coal dust with the used heat transfer medium is discharged into the atmosphere and another part with the returned heat transfer medium is fed into the furnace, where it burns.

In order to avoid pollution of the air space, the heat carrier to be discharged should be subjected to wet cleaning, and this leads to the formation of a large amount of chemically polluted waste water. Therefore, the problem of environmental protection cannot be completely eliminated.

When producing the coke in a coke oven battery, which consists of 65 coke chambers with a content of 41.6 m ³ each, the amount of heat transfer medium used is about 50,000 nm ³ / h, the 0.3% carbon oxide, other toxic components and at least 50 mg / nm ³ contains finely dispersed coal dust.

As a result of contact between the heated coke at a temperature of 1000 to 1050 ° C. and the gas in the cooling stage, coke burns off.

The necessary construction of special systems for the heat treatment of the coal and for cooling the coke as well as the use of additional personnel to operate these systems lead to a considerable increase in material costs.

If the process for extracting coke, which includes the heat treatment of the feed coal and the cooling of the coke in the dry process, is also economically justifiable is (thanks to some positive effects), a wide introduction of the process into industrial practice is nevertheless delayed by the presence of the above-mentioned defects and the advantages that can be achieved cannot be fully realized.

In this connection, the solution to the above problems inherent in the known methods of heat treating the coal and cooling the coke is of fairly topical importance.

Disclosure of the invention

The object of the present invention was to develop such a coke extraction process which, under the conditions of an expanded coking raw material base, made it possible to increase the performance of the process, to eliminate coke losses, to reduce the amount of harmful substances to be evaluated in the environment and to simplify and cheapen the process.

The object was achieved by a method for coke extraction, which includes the heat treatment of the comminuted coal, its coking and the cooling of the coke produced, in which, according to the invention, the heat treatment of the comminuted coal is mixed by mixing it with the coke at a temperature of 600 to 1050 ° C with a mass ratio of the coal and coke to each other from 1.3 to 2.6: 1 in cocurrent, the coke being cooled to a temperature of 150 to 250 ° C and the coal to a temperature of 120 to 240 ° C is heated, after the end of the heat exchange process between the coke and the coal, the coal-coke genus is separated into coke and coal, which is then heated to a temperature of 120 to 240 ° C and fed to coking.

It is recommended to use the coke with a piece size of not less than 10 mm. This contributes to its better and more complete excretion in the separation of the coal-coke mixture after the heat exchange.

It is recommended to use the heated lens set Separate coal after its separation from the coke into two fractions, namely: into a fraction with a piece size of less than 3 mm and into a fraction with a piece size of more than 3 mm, the fraction of the input coal with the piece size of more than 3 mm is crushed until particles with a size of less than 3 mm are obtained, then they are mixed with the previously excreted feed coal with a size of less than 3 mm and passed on to coking. This contributes to an improvement in the technological properties of the input coal and to an increase in the quality of the coke obtained therefrom.

In the event of a fluctuation in the moisture of the starting coal, its mixing with the heated coke is carried out in the presence of water which is introduced in an amount of 10 to 80 kg per ton of starting coal. This stabilizes the temperature of the heating of the coal.

For the process of mixing the feed coal with the heated coke, a rotating drum at F _r = 0.015 to 0.2 is preferred as the heat exchanger, where F _r - ratio of the product of the squares of the speed of rotation and the diameter of the heat exchanger to the product of the acceleration the free fall and the average size of a piece of coke; at P ₌ (1.5 to 10). 10 ^-6 , where P - the ratio of the product of the speed of rotation of the heat exchanger and the load after the coal to the product of the diameter, the length of the heat exchanger, the bulk density of the coal and the acceleration of the free fall; at α = 0.15 to 0.4, where α - degree of filling of the heat exchanger volume. This increases the effectiveness of the heat exchange between the coal and the coke, reduces the abrasion of the coke pieces and prevents overheating of small parts of the coal.

The method according to the invention allows the investment intensity of the process to be reduced, the work output to be increased, the losses of coking coal and the Reduce coke, significantly reduce pollution and improve coke quality.

The reduction in investment intensity and the increase in work performance is achieved by combining the heat treatment of the input coal and the cooling of the coke into one process.

Thanks to this combination, instead of two plants, only one plant is required in the known method, which is implemented in the plant for the heat treatment of the input coal and the dry extinguishing plant for coke.

The reduction in the losses of coking coal and coke in the above-mentioned process is achieved in that in this case the conditions which led to the combustion of feed coal and coke in the known processes are excluded.

The reduction in environmental pollution in the proposed method is due to the fact that there is no gaseous heat transfer medium in this process that should be evaluated in the atmosphere. With this method, only water vapors are ejected into the atmosphere, which are formed by the evaporation of the moisture contained in the coal.

The above and other advantages of the invention can be understood from the following more detailed description of the method with reference to the drawing, on which the basic diagram of the coke extraction process is shown.

The glowing coke coming from a coke oven battery 1 is passed via a line 2 into a storage bunker 3, where the coke is at a temperature of 1000 to 1050 ° C. for a certain time under the isothermal conditions. This contributes to a stabilization of the temperatures over the entire coke volume, the course of the isothermal reactions and the hardening of the coke.

From the storage bunker 3, the coke is fed via a line 4 to a separator 5, in which it is separated into two classes, in small coke with a piece size of less than 10 mm and in the piece coke with a piece size of more than 10 mm. The small coke (4 to 8% of the total amount) is passed over a line 6 for cooling by any method (wet method, evaporation method, conductive heat exchange). The piece of coke is passed from the separator 5 at a temperature of 600 to 1050 ^° C. via a line 7 into a heat exchanger 8. For the implementation of the method according to the invention, a heat exchanger of any construction can be used, in which it is possible to mix the feed coal and the coke, for example, a heat exchanger with a rotating drum and the like. The feed coal in a mass ratio to the coke of 1.3 to 2.6: 1 reaches the heat exchanger 8 via a line 10 from a bunker 9, depending on the requirements for the final temperature of the feed coal heating in the heat exchanger 8. The feed coal and the heated piece coke are in the heat exchanger 8 mixed together; Thanks to a difference between the heat-emitting and the heat-absorbing surfaces and the shielding effect of the moisture of the coal, the coke is cooled to a temperature of 150 to 250 ° C and the coal is heated to a temperature of 120 to 240 ° C at the same time. The heating of the coal and the cooling of the coke are relatively slow (5 to 7 minutes). This is why the polydisperse mass of the input coal is heated evenly enough without particle heating, coal decomposition and its coking on the coke surface. This contributes to the maintenance of the physico-chemical properties of the coal and its caking.

The piece of coke, which cools down relatively slowly, is not exposed to any thermal shock, as is the case with cooling using the wet extinguishing method. This ensures a high level of uniformity in the grain composition of the coke and increases its strength.

When mixed with the coal during the heat exchange, the coke becomes a gentle mechanical Treatment which also contributes to a better strength of the coke. After the heat exchange has ended, the coal-coke mixture is subjected to a separation by piece size in a separator 11, for example on a sieve grate. Since the coke participating in the heat exchange consists of pieces of a size of more than 10 mm and the insert coal is represented by particles of a size of less than 10 mm, the heated insert coal is completely separated from the coke during the separation.

During the mixing process, part of the small coke gets into the coal as a result of the mechanical treatment. However, this does not adversely affect their technological properties.

After leaving the separator 11, the cooled piece of coke is passed over a line 12 as the end product to a sorting plant and the heated coal is passed over a line 13 to a separator 14. In the separator 14, the insert coal is separated into two fractions with a piece size of less than 3 mm and with a piece size of more than 3 mm. The insert coal with a piece size of less than 3 mm is fed to the coke oven battery 1 via a line 15 for coking and the particles of the insert coal with a size of more than 3 mm are fed to a crusher 17 via a line 16 for comminution. The purpose of comminution is to obtain particles with a size of less than 3 mm. This comminuted feed coal fraction is fed via a line 18 to the common feed coal stream, which is fed via line 15 to the coke oven battery 1 for coking.

As technology-related excretions of the coke mine process according to the invention in the stage of cooling the coke and the heat treatment of the charge coal, water vapors are to be mentioned that form when the charge coal is heated; these water vapors are passed via a line 19 into a dust separator 20, to which water flows via a line 21 is fed. The water vapors emerging from the heat exchanger 8 take part of coal dust with, which is easily separated in a dust separator 20 and is fed back as' slurry via a line 22 into the heat exchanger 8 together with the starting coal.

The water vapors, cleaned of dust, are emitted into the atmosphere via line 23. The content of harmful substances in these vapors is not high and does not lead to any pollution of the environment, as is the case with the known method of coke extraction, which includes the heat treatment of the feed coal with a gaseous heat transfer medium and the cooling of the coke by the dry quenching process.

As a result of the removal of moisture from the coal and in part due to the penetration of the small coke into the coal during the heat exchange process, the debris density of the coal increases, the coking conditions improve and the coking period is shortened, i.e. ,. the speed of the process increases.

The increase in the bulk density of the feed coal and the increase in the coking rate lead to a 40% increase in the performance of the coke oven battery 1 and contributes to an improvement in the coke quality in comparison with the conventional method:

When the coal is mixed with the coke, 1.2 to 1.5% of the small coke gets into the coal, which, as already mentioned above, does not deteriorate the technological properties of the coal, but on the contrary, the bulk density of the Charcoal increases, and when it returns, together with the char for coking, promotes an increase in the yield of the Huttenkoks.

According to the invention, piece coke serves as a heat transfer medium in the present method, which is passed into the metallurgical production after the heat exchange; therefore, the used heat transfer medium does not need to be left out, as is the case with the known technology of heat treatment of the insert coal with a gaseous heat carrier is the case.

The moisture of the starting coal and its initial temperature can be changed depending on the temperature fluctuations in the environment. This changes the physical properties of the material, which can lead to fluctuations in the final temperature of the coke cooling and the heating of the coal.

In order to be able to stabilize the temperature of the feed coal heating and the coke cooling, 24 water in a quantity of 5 to 50 kg per ton of coke is added to the heat exchanger d via a line. The water is added to 1/3 length of the heat exchanger in its end part. The quality of the coke to be produced therefrom is improved by avoiding overheating of the insert coal and by stabilizing its values.

Preferred embodiment of the invention

• F_r (Froude-Zahl), P und α gleichzeitig eingehalten werden.
  
  
  
  F_r - Froude-Zahl
• P - Volumenbelastung der Einsatzkohle auf die transportierende Trommelfläche;
• n - Trommel drehzahl;
• D - Trommeldurchmesser
• L - Trommellänge
• G - Belastung nach der Einsatzkohle
• ρ - Schüttdichte der Einsatzkohle
• g - Fallbeschleunigung
• d - Durchschnittsdurchmesser der Koksstücke
• α - Trommelfüllfaktor.

The best embodiment of the invention is the variant in which the glowing coke is separated at a temperature of 600 to 1050 ° C. in the separator 5 into small coke with a size of less than 25 mm and piece coke with a size of more than 25 mm. A rotary drum is used as the heat exchanger. A uniform mixing of the starting coal and the coke is achieved in DC operation. The process is carried out at values of the relative speed of rotation of the drum, the load on the transporting surface and the degree of filling of the drum volume that the relationships:

• F _r (Froude number), P and α are observed at the same time.
  
  
  
  F _r - Froude number
• P - volume load of the insert coal on the transporting drum surface;
• n - drum speed;
• D - drum diameter
• L - drum length
• G - load after the coal
• ρ - bulk density of the coal
• g - acceleration of gravity
• d - average diameter of the pieces of coke
• α - drum fill factor.

Under these conditions, the effectiveness of the heat exchange increases in a shorter time of contact between the feed coal and the coke, which leads to a more uniform heating of the coal particles and to cooling of the coke pieces. The coke pieces are exposed to less abrasion, and as a result fewer coke pieces get into the coal.

When the relationships F _r , P and α are exceeded beyond the limits defined by the invention, the time of contact of the insert coal with the coke increases, the amount of small coke entering the insert coal increases, which leads to a deterioration in the technological properties the input coal, reduction in the strength values of the coke and increase in the specific ejections of toxic gaseous components contained in the steam to be ejected.

Carrying out the process according to the invention in accordance with the preferred embodiment makes it possible to significantly improve the strength properties of the coke and to reduce the volume of harmful emissions into the atmosphere by 15 to 20% in comparison to the other forms of process control.

As can be seen from the detailed description of the invention and from its preferred embodiment, the heat treatment of the insert coal takes place simultaneously with the cooling of the coke. The method according to the invention is simpler and requires less investment in its implementation than the known method, which involves heat treating the insert coal with a gaseous heat transfer medium and cooling the Includes coke after the dry extinguishing process as separate stages.

Since the coke from coke ovens serves as a heat transfer medium, the energy expenditure required to generate the heat transfer medium (as is the case with systems for heating the input coal with a gaseous heat transfer medium) is excluded and there is no need for an intermediate medium Cooling down of the coke, as is customary in dry quenching systems.

In addition, the invention precludes ejection of the used heat carrier into the environment and consequently its pollution.

Increasing the bulk density of the heated feed coal and increasing the rate of coking make it possible to increase the efficiency of the coke extraction process by 40% compared to conventional technology by using up to 70% low-baking coal with practically no deterioration in coke quality.

The quality indicators of the coke produced are of the same quality level as in the known method, which includes the heat treatment of the input coal with a gaseous heat transfer medium and the cooling of the coke using the dry quenching method.

The advantage of the coke extraction process according to the invention over the known processes is thus a considerable reduction in the harmful emissions into the environment, a reduction in the expenditure of material and energy, and a significant simplification of the process and in an increase in the productivity of the process. Thanks to a simplified technological scheme, the process can be easily implemented under industrial conditions. All of this characterizes the process according to the invention in a commercially favorable manner in comparison with the known processes.

For a better understanding of the present invention, examples of the specific implementation of the coke extraction process are given with reference to the drawing.

Example 1.

The storage bunker 3 is loaded with 15400 kg of coke at a temperature of 800 ° C.

In the separator 5, the coke is separated into small coke (1100 kg) with a piece size of less than 25 mm, which makes up about 7%, and into piece coke (14300 kg) with a piece size of more than 25 mm.

The storage bunker 9 is fed with 20,100 kg of crushed coal with an initial moisture content of 9%. Lump coke and coal are fed into the heat exchanger 8, where they are mixed together in direct current in a ratio of 1: 1.4. The heat exchange time is 408 s. The vapors emerging from the heat exchanger 8 are dedusted in the dust separator 20, to which water is supplied, during wet operation and are discharged into the atmosphere after they have been cleaned. From the dust separator 20, the water is passed along with dust in the form of slurry over the line 22 for mixing with the coal. The amount of water to be dedusted was 162 kg for the entire process cycle.

After the heat exchange has ended, the coal-coke mixture is separated into coke and feed coal in the separator 11. The temperature to which the feed coal was heated at the outlet from the heat exchanger 8 is 160 ° C. The amount of coal used to leave the heat exchanger is 18,600 kg. It was determined by analysis that the heated insert coal contains 1.6% small coke that has formed during the heat exchange process.

• Ausbeute an flüchtigen Bestandteilen V ^daf - 29,3%
• Dicke der plastischen Schicht Y - 13,8 mm
• Aufschwellindex I - 25,3%
• Schüttdichte ρ- 860 kg/m³

The quality of the heated coal is characterized by the following parameters:

• Yield of volatile constituents V ^daf - 29.3%
• Thickness of the plastic layer Y - 13.8 mm
• Swell index I - 25.3%
• Bulk density ρ- 860 kg / m ³

The temperature to which the coke emerging from the heat exchanger has been cooled is 200 ° C.

The coke losses in the cooling after the present There are practically no end processes.

The heat loss of the process is 5%.

The total emissions of toxic gaseous components contained in the steam to be ejected are 167 g / t coke.

The heated coal with a temperature of 160 ° C is passed to the coke oven battery 1 for coking.

The amount of coke produced after coking is 14,510 kg, which corresponds to a coke yield of 78% based on the coal used.

• Festigkeit M25 - 89,0
• Abreibbarkeit M10- 7,0

The quality of the coke is characterized by the following parameters:

• Strength M25 - 89.0
• Abrasion M10- 7.0

• - eine um 1,2% höhere Koksausbeute aus der Einsatzkohle
• - einen um 50 bis 60% geringeren Auswurf von toxischen Stoffen
• - einen um 43% geringeren Materialaufwand für die Realisierung des Prozesses.

In comparison to the known method, which includes the heat treatment of the feed coal with a gaseous heat transfer medium and the cooling of the coke by the dry quenching method; the method according to the invention ensures:

• - A 1.2% higher coke yield from the input coal
• - A 50 to 60% reduction in the emission of toxic substances
• - 43% less material required to implement the process.

Example 2. -

The process is carried out similarly as in Example 1.

The storage bunker 3 is charged with 8700 kg of coke at a temperature of 1000 ° C.

In the separator 5, the coke is separated into small coke (600 kg) with a piece size of less than 25 mm, which is 7%, and into piece coke (8100 kg) with a piece size of more than 25 mm.

The storage bunker 9 is charged with 20200 kg of crushed coal with an initial moisture of 9%.

The piece coke and the insert coal are in the Heat exchanger 8 passed where they are mixed together in DC operation in a ratio of 1: 2.5.

The heat exchange time is 365 s.

As in Example 1, the water vapors are discharged into the atmosphere after dedusting. The amount of water for ena deafness is 163 kg.

The temperature of the coal heating is 150 ^o C. The amount of coal after the heat exchange is 18600 kg, the small amount of coke 1.2%.

• Ausbeute an flüchtigen Bestandteilen V^daf -30,0
• Dicke der plastischen Schicht Y -14,0
• Aufschwellindex I -27,1
• Schüttdichte f -860 _kg/m³
• Die Temperatur der Koksabkühlung beträgt 170°C.

The quality of the heated coal is characterized by the following parameters:

• Yield of volatile components V ^daf -30.0
• Thickness of the plastic layer Y -14.0
• Swell index I -27.1
• Bulk density f -860 _k g / m ³
• The temperature of the coke cooling is 170 ° C.

The heat losses are 5%.

The total emissions of harmful substances are 160 g / t coke.

The coke losses are practically absent.

The amount of coke produced is 14,510 kg, which corresponds to 78% of the input coal.

• Festigkeit M25 - 89,2%
• Abreibbarkeit M10 - 6,9%.

The quality of the coke is characterized by the following parameters:

• Strength M25 - 89.2%
• Abrasion M10 - 6.9%.

The heated coal with a temperature of 150 ° C is passed to the coke oven battery 1 for coking.

Example 3.

The process is carried out in a manner similar to that in Example 1, both with regard to the heat treatment of the charge coal, and with regard to the amount of coke and the ratio given between them.

The difference, however, is that the process of heat treating the coal and cooling the coke by introducing it into the atomized water heat exchanger is 19 kg per ton of coal coal is led.

As a result, the temperature of the heated coal is 140 ° C and that of the cooled coke is 180 ° C.

The heated coal is characterized by the following parameters:

• Festigkeit M25 = 89,6%
• Abreibbarkeit M10= 6,9%.

The quality of the coke after coking the heated coal is characterized by the following parameters:

• Strength M25 = 89.6%
• Abrasion M10 = 6.9%.

The heated coal with a temperature of 140 ° C is passed to the coke oven battery 1 for coking.

Examples 4 to 7.

The process is carried out similarly in Examples 1 to 3. A drum heat exchanger is used to mix the coal in which the length and diameter of the heat exchange zone are 1.6 and 6 m, respectively.

The temperature of the coke used to heat the coal is 970 ° C.

The mass ratio of coal and coke to each other that get into the heat exchanger is 2.5: 1.

The conditions for carrying out the process according to the examples mentioned and their results are summarized in a table.

Industrial applicability

The present invention can be implemented in coke chemical production to obtain the coke used in the metallurgical industry.

Claims (5)

1. A process for the extraction of coke, which includes the heat treatment of the comminuted coal, the coking of the heated coal and the cooling of the coke obtained, characterized in that the heat treatment of the comminuted coal by mixing it with the coke at a temperature of 600 to 1050 ° C at a mass ratio of the input coal and the coke to one another of 1.3 to 2.6: 1 in cocurrent, the coke being cooled to a temperature of 150 to 250 ° C. and the input carbon being heated to a temperature of 120 to 240 ° C. after the end of the heat exchange process, the coal-coke mixture is separated into coke and feed coal, which is then fed to the coke heated to a temperature of 120 to 240 ° C. 2. The method according to claim 1, characterized in that is used for the heat exchange of the coke with a piece size of not less than 10 mm. 3. The method according to claim 1, characterized in that one separates the heated coal before coking in two fractions-namely: in a fraction with a piece size of more than 3 mm and a fraction with a piece size of less than 3 mm, thereby _' the faction with one. Shredded piece size of more than 3 mm until particles with a size of less than 3 mm are obtained, then they are mixed with the fraction with a piece size of less than 3 mm and this mixture is passed to coking. 4. The method according to claim l, characterized g e - indicates that the coal is mixed with the coke with the addition of water in an amount of 10 to 80 kg per ton of starting coal. 5. The method according to claim 1, characterized in that the mixing of the starting coal and the coke in a rotating heat exchange drum in: _Fr _ ₀ , ₀₁₅ to 0, ₂ ,
where F _r - ratio of the product of the squares of the speed and the diameter of the heat exchanger to the product of the acceleration due to gravity and the diameter of the average size of the piece of coke; P ₌ (1.5 to 10). 10 ^-6,
where P - the ratio of the product of the speed of the heat exchanger and the load after the coal to the product of the diameter, the length of the heat exchanger, the bulk density of the coal and the acceleration due to gravity; 0.15 to 0.4,
where there is α fill factor of the heat exchanger volume.