EP0030376A2 - Process and apparatus for drying and preheating moist coal - Google Patents

Abstract

1. Process for drying and heating moist coal, in particular fine coal and fines, in which heat is supplied to the coal to be dried via an inert gas circulation which can be heated by means of a heat exchanger, and the dried and heated coal is protected from the access of oxygen by a part circulation of the inert gas, characterised in that, during the start-up procedure before moist coal is introduced, the air present in the unit is circulated and, during this, heated up via a heat exchanger, that those parts of the unit which come into contact with the circulation are warmed by means of the heated-up air circulation to a temperature which avoids the condensation of water vapour, before water is sprayed, or steam introduced, into the heated-up air circulation and the air circulation is enriched in steam, the proportion of oxygen being lowered to below 2% by volume and the inert gas circulation thus being formed, before moist coal is introduced in co-current into the inert gas circulation for drying.

Description

Alfelder Eisenwerke Carl Heise KG, formerly Otto Wesselmann & Cie., 3220 Alfeld

Method and device for drying and heating moist coal

The invention relates to a method for drying and heating moist coal, in particular fine and very fine coal, in which the coal to be dried is supplied with heat via an inert gas circuit, which can be heated with the aid of a heat exchanger, and the dried and heated coal with a Partial circuit of the inert gas is protected from the entry of oxygen. The invention also shows an apparatus for performing the method.

DE-A 28 10 694 shows a method of the type described in the introduction, in which fine coal for the production of high-quality coke with an oxygen-free heating medium is dried and heated. Water vapor is used as the inert gas, which develops when the coal to be dried is heated from the moisture that is carried in by the moist coal. The inert gas circuit is indirectly heated by a heat exchanger. The inert gas circuit must also be cleaned in a dedusting system, with the entrained coal particles being separated. Used as _E nt dedusting plant a cyclone used, then it is due to the low density of coal and large fines insufficient cleaning. In addition, the fine parts of the coal are also deposited on the heat exchanger, and considerably impair the heat transfer. If, however, a cloth filter is used, then temperature problems arise. If the temperature of the inert gas in the filter is too high, there is a risk that the filter cloths will burn. If, on the other hand, the temperature is too low, condensate forms and the carbon particles accumulate with the condensate on the filter cloths, so that the filter resistance increases. However, this can cause the inert gas circuit to break down because the filter resistance becomes too great. If, on the other hand, electrostatic filters are used, the fine, entrained coal particles must first be coated with water in order to be able to apply electrical charges. However, the water has a poor affinity for the hot coal particles. In addition, coal sludge is ultimately produced in this electrostatic precipitator, that is to say fine, particularly moist coal, while the method is intended to dry the coal.

In addition, there are large ones in the known method Problems when starting and stopping the system; because moist coal is first introduced into the hot drying device. When starting up, only hot air is initially available in the circulation, so that its oxygen content can very easily lead to self-ignition of the coal. As a result, explosions and explosions can occur. On the other hand, when it is switched off, condensate and dirt occur as a result of the temperature drop and when using a cloth filter system.

The known method works on the countercurrent principle. This is disadvantageous insofar as the inert gas heated in the heat exchanger with its hottest inlet temperature meets the already dried coal at the outlet of the drying system. Here there are signs of overheating. In addition, the hot fines from the coal are taken in countercurrent. These migrate back to the entrance of the drying facility and can be deposited there again on the wet coal particles. This results in an accumulation of the fine particles in the drying device, so that their resistance increases. This affects the inert gas cycle.

DE-A 26 59 335 shows a cabbage drying and heating system which works with an entrained-flow dryer and a downstream entrained-flow heater for the coal and in which a directly fired gas circuit is firstly conducted in direct current through the entrained-current heater and then through the entrained-current dryer. Air in the form of combustion air is also introduced into the gas-operated combustion chamber, so that the oxygen content in the circuit of the heat transfer medium is poor is manageable. In spite of vapor recirculation, deflagration phenomena and explosions cannot be avoided with this known coal heating system. The system also works with an electrostatic precipitator, whereby the coal separated there is added to the dried coal. In the circuit of the heat transfer medium, two short-circuit lines are arranged, both of which bridge the entrained-flow dryer and serve to raise or regulate the temperature in a cyclone separator and in the electrostatic filter. The fan provided in the circuit of the heat transfer medium conveys in addition to the vapor return immediately into the electrostatic filter and then into the chimney, so that there is an additional risk that air at leaky points in the system and thus oxygen will get into the circuit of the heat transfer medium.

From DE-B 26 26 653 a two-stage single-tube entrained flow dryer is known, which is operated in direct current. Here, too, the heat transfer circuit is heated directly, excess oxygen being introduced via the combustion air of the gas burner. Here, too, there is a risk that the oxygen content in the heat transfer medium will easily accumulate to such an order of magnitude that deflagration, fires and explosions can occur. This is particularly the case during the start-up process when there is only hot air with the known high oxygen content in the heat transfer circuit.

From "Processing Technology", Issue 12, 1978, pages 581 to 586, the person skilled in the art on page 584 in connection with floating gas dryers, that is in principle different from the subject of the application, is recommended to set the oxygen content of the hot gas to a maximum of 14%, that is just stay below that limit. But that is the danger of Self-ignition and deflagration in the floating gas dryer have not been eliminated. For safety of the actual drying system, a cooling option by injecting water and steam is recommended. A C0 ₂ inerting system should be available for the electrostatic filter. Furthermore, the expert is recommended to first fill the system with steam when starting up and then inject water, which is to be gradually replaced by sludge to be dried. However, there is a risk that the steam will condense immediately on the cold walls of the system when the steam is introduced, so that the steam introduced must be removed from the system again essentially in the form of condensed water. In addition, only very small amounts of steam can remain in the system in the cold air until the saturation limit of the steam absorption capacity of the cold air is reached. It is certainly not below the defined limit of 14% oxygen. Following this process, water is to be injected so that the system, which may have been warmed up by slow steam filling, is cooled down again by the water, so that the low proportion of steam in the air is reduced even further by the temperature drop. Furthermore, the water should be gradually replaced by sludge to be dried. There are strong doubts whether the specified limit of 14% oxygen can be reached in this way. Under no circumstances, however, is the risk of deflagrations, burns or the like eliminated.

The invention has for its object to develop the method of the type described in such a way that a system can be started up and shut down without the risk of deflagration, burns and explosions. Furthermore, such "Coal drying plant solves the problems associated with dedusting and maintaining the filter effect.

The process according to the invention is characterized in that, during the start-up process, before the coal drying begins, the air present in the system is circulated and heated via a heat exchanger in that water or water vapor is introduced into the heated air cycle and the air cycle is enriched with water vapor and so on Intertgas cycle is formed. An inert gas circuit is therefore first created from the air circuit without drying the coal by indirectly heating the air present in the system, that is to say without necessarily introducing further oxygen. Water or water vapor is then introduced into the heated air circuit, water introduced as a result of the heat evaporating. It goes without saying that air mixed with water vapor is also discharged or led out of the circuit. However, this creates the possibility of enriching the air circuit with water vapor until an inert gas circuit is formed, ie until the oxygen content is so low that deflagration and explosions are no longer to be feared. Only then can the coal to be dried be safely introduced into the cycle. However, it is also possible to introduce liquid water into the circuit using the drying device and to use the amount of heat already introduced indirectly via the heat exchanger to evaporate and heat the water to water vapor. This makes sense insofar as liquid water, which has to be evaporated, is later introduced when the wet coal is dried. In the inert gas circuit is first by An enrichment with water vapor, the oxygen content is reduced below 2%, preferably below 1%, before moist coal is introduced for drying. It is understood that at this point an excess amount of gas is already released into the chimney via an overflow valve.

During the shutdown process, the dried coal is first led out of the drying zone. The inert gas cycle is maintained by introducing water or steam until all coal has left the weighing and mixing device. Only then will the inert gas circuit be replaced by an air circuit.

The inert gas circuit is passed in cocurrent over the coal to be dried, so that an enrichment of the fine fractions of the coal in the drying device is avoided. At the same time, this means gentle treatment of the coal and, in contrast to drying in the entrained flow process, the circulation of considerable amounts of gas and the mechanical stress on the coal are thereby avoided.

The device for drying and heating moist coal, in particular fine and ultra-fine coal, works with a drying device, an inert gas circuit which can be heated indirectly via a heat exchanger and which is passed once through the drying device and in a partial circuit via a mixer for dried coal, with a dedusting device in the inert gas circuit and with a heat source connected to the heat exchanger. According to the invention, the drying device is a driven drying drum which is connected to the inert gas circuit in direct current and which is a pre-separator and cooler in the inert gas circuit as well as a cloth filter dedusting; the inert gas circuit has a lockable supply line for water or steam and a further lockable supply line for air. By using a drying drum in a direct current process as a drying device, the coal is gently dried, the highest temperature of the inert gas circuit acting on the moist coal, so that overheating at the exit of the drying drum on the dried coal is avoided and the temperature profiles can be controlled more easily and better. This also makes it possible to use a pre-cutter and cooler as well as a cloth filter dedusting system in the inert gas circuit, which can achieve the required cleaning of the inert gases when working dry. The lockable supply line for water or steam serves for the start-up process, while the further lockable supply line for air is required when the system is switched off.

The inert gas circuit has two short-circuit lines, each provided with controllable shut-off devices, one of which is connected between the heat exchanger and the drying drum and leads into the line between the drying drum and the pre-separator and cooler, while the other branches off after the cloth filter dedusting and after the downstream fan and front heat exchanger and While the first short-circuit line is used to increase the temperature in the cloth filter dedusting, the second short-circuit line serves to lower the temperature in the cloth filter dedusting. It is understood that in this way the cloth filter dedusting can be carried out in an optimal temperature range that falling below the dew point and thus education of sulphurous acid and water condensation. The upstream pre-separator and cooler can also be used to lower the temperature in the cloth filter dedusting. The cooling device on the pre-separator expediently consists of several fans which can be switched on or off accordingly.

The partial circuit of the inert gas circuit intended to protect the dried coal branches off after the fan and is returned to the inert gas circuit, bridging the drum between the drying drum and the pre-separator and cooler. The dried coal is thus effectively protected against the entry of atmospheric oxygen even after it has left the drying drum until it has been subjected to a desired processing. Thus, for example, the material silo, the weighing and mixing device and the conveyor section of the coal are rendered inert. This can be done by depositing it in a silo. It is also possible to coat the dried coal with a binder, preferably a bituminous binder; this is particularly useful if the coal is then to be coked. Starting from the fan, a controllable shut-off device is arranged both in the inert gas circuit upstream of the heat exchanger and before the branching of one short-circuit line and in the branching partial circuit. These two shut-off devices control the quantity distribution of the inert gas for the inert gas circuit on the one hand and for the partial circuit on the other. It goes without saying that this quantity control can also influence the temperatures at the respective parts of the system. In the pitch circle Circulation of the inert gas to protect the dried coal can include a mixer, a weighing device and an intermediate silo. It goes without saying that other devices for the dried coal can also be provided here, which are then expediently also included in the partial circuit, provided that the temperature of the dried coal is still in a dangerous range in such plant parts.

The lockable supply line for water or water vapor is expediently connected to the inert gas circuit at the entrance to the drying drum. In this case, all you need is a water supply line and a shut-off device, while the drying drum itself can be used to evaporate the water, as is also done later for the main purpose of the system, namely the drying of the coal. The shut-off supply line for air, on the other hand, is expediently connected to the inert gas circuit between the dust filter and the fan, so that here air is sucked in and mixed with the inert gas in a simple manner. The temperature in the dedusting system is initially not reduced, so that no condensation can occur.

The heat exchanger connected to the inert gas circuit is, on the other hand, connected to a heating circuit which has an exhaust gas recirculation in which a controllable shut-off element is provided. In this way, the heat of the waste gas from this heating circuit can be used by recirculation and, in this sense, the temperature control of the heating circuit can be influenced.

• Die Vorrichtung zum Trocknen und Erhitzen von feuchter Kohle weist ein Materialsilo 1 mit Dosiereinrichtung auf, von dem über einen Gutförderer 2 feuchte Kohle abgezogen werden kann. Am Ende des Gutförderers 2 befindet sich eine Zellenradschleuse 3 im Bereich des Einlauftrichters der Trockentrommel 4, die um ihre Längsachse drehbar gelagert ist und angetrieben ist, so daß sich die Kohle beim Durchgang durch die Trockentrommel 4 immer in einer kaskadenförmigen Bewegung befindet.

The invention is illustrated and further described on the basis of a system shown schematically in the drawing:

• The device for drying and heating moist coal has a material silo 1 with a metering device, from which 2 moist coal can be drawn off via a material conveyor. At the end of the material conveyor 2 there is a cellular wheel sluice 3 in the area of the inlet funnel of the drying drum 4, which is rotatably supported and driven so that the coal is always in a cascade-shaped movement as it passes through the drying drum 4.

The system also has a pre-separator and cooler 5, as well as a cloth filter dedusting device 6 connected downstream thereof. A fan 7 is provided downstream for circulating the heat transfer medium or the inert gas circuit and the partial circuit. A heat exchanger 8 is used for indirect heating of the inert gas circuit. The heat exchanger 8, on the other hand, is connected to a heating circuit 9, which ultimately leads to the exhaust stack 10 and has an exhaust gas recirculation 11. In this exhaust gas recirculation 11, a mixed gas fan 12 and a controllable shut-off device 13 are arranged. A burner 14 is heated with gas or another medium which is drawn off via a line or a storage tank 15. The combustion air for the burner 14 is brought in via the air fan 16. As can be seen, the exhaust gases can be returned via the return line 11 after passing through the heat exchanger 8 and mixed in a mixing chamber 17 with the combustion exhaust gases.

The inert gas circuit leads with a line 18 from the heat exchanger 8 to the entrance into the drying drum 4. After passing through the drying drum 4, the inert gas circuit of line pieces 19, 20, 21 22 and 23 completed. As can be seen, the line piece 19 is connected between the output of the drying drum 4 and the input of the pre-separator and cooler 5, which, moreover, can be blown with cooling air by a blower (not shown) according to the arrows 24 and thus the temperature of the inert gas can be reduced. The line piece 20 connects the outlet of the pre-separator and cooler 5 with the cloth filter dedusting 6; the output of which is connected to the blower 7 via the line piece 21. From this, the line section 22 leads to a controllable shut-off device 25, from which the line section 23 leads to the heat exchanger 8. The inert gas circuit 18 to 23 is formed from the line 18 and the line sections 19, 20, 21, 22 and 23. In the inert gas circuit, two short-circuit lines 26 and 27 are provided, in which controllable shut-off devices 28 and 29 are arranged. By opening the shut-off device 28, the temperature of the inert gas in the pre-separator 5 and in the cloth filter dedusting 6 can be increased. By opening the short-circuit line 27 or the shut-off device 29, on the other hand, the temperature in question can be lowered, even in the drying drum 4.

At the entrance of the drying drum 4, a feed line 30 for water or water vapor and a control device 31 are provided, which are required for start-up purposes. A further supply line 32 for air, in which a shut-off element 33 is arranged, opens into the line section 21. The feed line 32 is required when the system is switched off. The dried coal passes from the outlet of the drying drum 4 via an encapsulated conveying device 34 into a bucket elevator 35 and from there into an intermediate silo 36, from which it can be transferred in batches to a weighing device 37, from which the coal in turn reaches the mixer 38. The coal can then finally be deposited in a silo 39 or be used for the corresponding purpose. In the mixer 38 it is possible to coat the dried coal with a binder, preferably a bituminous binder. This is fed from the binder tank 40 into the mixer 38 via the injection device 41. The binder tank 40 is kept at the desired processing temperature by a thermal oil heating unit 42.

In addition to the inert gas circuit 18 to 23 as the main circuit, the partial circuit 43 to 47 formed from the line pieces 34 to 47 branches off from the line piece 22. This partial circuit 43 to 47 of the inert gas protects the dried coal and the relevant parts of the plant over which it is guided.

Not only the short-circuit line 24 branches off from the line piece 23, but also the inert gas outlet line 48, in which the adjustable pressure relief valve 49 is provided and which ultimately leads to the exhaust stack 10. An overpressure is always maintained in the inert gas circuit 1 to 23 and in the partial circuit 43 to 47 via this pressure relief valve 49. At the same time, gas is continuously released to the flue gas stack 10 via the pressure relief valve 49 both during the start-up phase and during the operation of the installation, because the water introduced or the coal entrains it Water is continuously enriched with water vapor.

The pre-separator and cooler 5 as well as the cloth filter dedusting 6 are connected to the bucket elevator 35 via screw conveyors 50, so that the dry coal separated in the pre-separator 5 and the cloth filter dedusting 6 is added again to the dried coal brought up via the conveying line 34.

To start up the system, starting from system parts filled with air, the fan 7, the drying drum 4 and various other system parts are started. The heating circuit 9 is then released by igniting the burner 14 for the development of heat, the associated system parts such as air fan 16 and mixed gas fan 12 also having to be switched on. Heat is transferred to the circuit filled with air via the heat exchanger 6. When a temperature of 180 ° C. is reached in front of the pre-separator and cooler 5, water is sprayed into the drying drum 4 by the control device 31 for water via the feed line 30. The water evaporates through the hot inlet gases. The resulting steam increases the amount of vapors in circulation. When a certain overpressure on the drying drum is reached, the controllable overpressure valve 49 is set ready for opening so that it can discharge a partial gas flow into the exhaust gas stack 10. The amount of water supplied is measured so that the water vapor produced is sufficient to reduce the oxygen content in the circulating vapors below 2%, preferably below 1%. This start-up process will take about 5 minutes. This can be used to start drying the coal by switching on the material conveyor 2 and removing moist coal from the material silo 1 and feeding it to the drying drum 4 via the cellular wheel lock 3. It goes without saying that at this point in time no more water is inserted via the feed line 30. The moist coal to be dried reaches the material silo 1 in some way, for example with the aid of a shovel loader. The material conveyor 2 is equipped with a direct current control drive. The quantity discharged can be measured volumetrically by hand or set manually from a control center. The amount of coal to be dried should be kept constant during operation. The interior of the drying drum 4 is largely airtight against the environment. Above all, no atmospheric oxygen can penetrate, since the inert gas circuit 18 to 23 is operated at the sealing points of the drying drum under a corresponding excess pressure. The temperature of the dried coal present at the end of the drying drum 4 is specified as a setpoint and compared in a controller. When the value falls below the setpoint, the shut-off device 25 on the pressure side of the fan 7 is opened, so that the amount of vapors in the inert gas circuit 18 to 23 is increased. If the target value of the temperature of the coal at the outlet of the drying drum 4 is exceeded, the amount of vapors is reduced by the control devices described above.

The entry temperature of the hot vapors into the drying drum 4 should be about 450 ° C. If the value falls below this target value, the gas supply to the burner 14 is increased. By introducing more energy, the exhaust gas temperature of the heating circuit 9 rises, so that too the temperature of the inert gas circuit 18 to 23 is raised via the heat exchanger 8. When the setpoint of the temperature of the heating circuit 9 is exceeded at the entrance to the heat exchanger, which is approximately 1,100 ° C., the shut-off device 13 in the heating circuit 9 is opened. As a result, an increased recirculation of the exhaust gases at approximately 300 ° C. is initiated, whereby the exhaust gas temperature in the mixing chamber 17 is reduced to the setpoint.

Water vapor is generated continuously during the drying process. Inert gas must therefore be blown off continuously or in batches at the overflow valve 49 into the exhaust gas stack 10. The fan 7 can, for example, be designed such that it has a total pressure difference of 70 mbar at 20 ° C., so that this pressure cannot be exceeded at any point in the inert gas circuit.

The vapors or the inert gas circuit are cleaned with the cloth filter dedusting device 6 and the upstream indirect pre-separator and cooler 5. Two control loops are required to protect the filter cloths from over and under temperature. If the predetermined setpoint temperature of, for example, 128 ° C. in the line section 20 is exceeded, the first half of the cooling fans is switched on according to the arrows 24. If the temperature continues to rise and reaches, for example, 132 ° C, all cooling fans are switched on. Nevertheless, if the temperature continues to rise and reaches, for example, 135 ° C., the gas supply in the burner 14 is switched off and the shut-off device 29 in the short-circuit line 27 is opened. As a result, the temperature in the inert gas circuit 18 to 23 is lowered with certainty Temperatures depend on the permissible temperature for the filter cloth used. If the specified setpoint temperature of 115 ° C. on the line section 20 is undershot, the shut-off device 28 in the short-circuit line 26 is opened, with the material conveyor 2 being switched off at the same time. As a result, the temperature in the pre-separator and cooler 5 and in the cloth filter dedusting 6 is raised again to such a value that critical conditions with regard to falling below the dew point cannot occur.

The dried coal present at the end of the drying drum 4 is conveyed into the intermediate silo 36 via the conveying device 34 and via a bucket elevator 35. At the same time, the coal, which is also dry and separated in the pre-separator 5 and in the cloth filter dedusting device 6, is fed via the conveyor screws 50. The coal is removed from the intermediate silo 36 by means of cellular wheel locks and fed to the weighing device 37. When the predetermined weight is reached, the cellular wheel sluices are switched off and the coal is introduced into the mixer 38. Simultaneously with the mixing of the mixer 38 with coal, the binder 41 is injected into the mixer 38 by the injection device 41. After the prescribed mixing time has expired, the mixer opens and the dried coated material, namely the coal, falls into a silo 39 or is used for further use. As can be seen, the partial circuit on the inert gas 43 to 47 protects the further system parts after the drying drum 4 and the heated, dry coal contained in them. The ratio of the inert gas, which is introduced into the inert gas circuit 18 to 23 after the fan 7, in relation to the amount of inert gas of the partial circuit 32 to 47 is achieved by the settings of the shut-off devices 25 and 51.

When the system is switched off, the material conveyor 2 is first stopped. Since the drying drum 4 no longer consumes as much heat, the temperature of the dry coal rises at the outlet of the drying drum. Likewise, the temperature of the inert gas in the line section 19 also rises. Water is now introduced into the drying drum 4 via the control device 31 for water. Even now, atmospheric oxygen is prevented from entering the system. After the mixing of the coal in the mixer 38 has ended, the water supply to the drying drum 4 is switched off and the air supply via the second feed line 32 is made possible by opening the shut-off device 33. The amount of vapors circulating increases further by sucking in air. Exhaust gas is continuously released into the exhaust stack 10 via the opened pressure relief valve 49. The proportion of water vapor is now constantly decreasing, while the proportion of air is increasing. Condensation of water vapor is prevented because the system is still at temperature. Finally, the gas supply to the burner 14 is switched off, so that no further energy is supplied and the temperature of the circuits can also be reduced with hot air. This is carried out until the temperature of the air has dropped below about 80 ° C. at all temperature measuring points. Then the control drives of the individual system parts, if they are not already shut down, are switched off.

Claims (13)

1. A method for drying and heating moist coal, especially fine and ultra-fine coal, in which heat is supplied to the coal to be dried via an inert gas circuit, which can be heated with the aid of a heat exchanger, and the dried and heated coal through a partial circuit of the inert gas the access of oxygen is protected, characterized in that during the start-up process before the coal drying begins, the air present in the system is circulated and heated by a heat exchanger that in the heated air circuit water or water vapor is introduced and the air circuit is enriched with water vapor and the inert gas circuit is formed. 2. The method according to claim 1, characterized in that in the inert gas circuit by enrichment with water vapor, the oxygen content is reduced to below 2%, preferably below 1%, before moist coal is introduced for drying. 3. The method according to claim 1 and 2, characterized in that during the shutdown process, the dried coal is first led out of the drying zone and then the inert gas circuit is replaced by an air circuit. 4. The method according to claim 1 to 3, characterized in that the inert gas circuit is carried out in cocurrent over the coal to be dried. 5.Device for drying and heating moist coal, in particular fine and ultra-fine coal, with a drying device, an inert gas circuit which can be heated indirectly via a heat exchanger and which is passed once through the drying device and in a partial circuit via a mixer for dried coal, with a dedusting device in the inert gas circuit and with a heat source connected to the heat exchanger, characterized in that the drying device is a driven drying drum (4) connected in direct current to the inert gas circuit (18 to 23), which in the inert gas circuit is a pre-separator and cooler (5) and a cloth filter dedusting ( 6) are connected downstream, and that the inert gas circuit has a lockable supply line (30) for Has water or water vapor and a further lockable supply line (32) for air. 6. The device according to claim 5, characterized in that the inert gas circuit (18 to 23) has two each with controllable shut-off devices (28, 29) provided short-circuit lines (27, 26), one of which (26) between the heat exchanger (8) and Drying drum (4) connected and into the line (19) between the drying drum (4) and the pre-separator and cooler (5), while the other (27) after the cloth filter dedusting (6) and after the fan (7) and in front of the heat exchanger ( 8) branches off and bridges the heat exchanger. 7. Apparatus according to claim 5 and 6, characterized in that the partial circuit intended to protect the dried coal (43 to 47) of the inert gas circuit branches off after the fan (7) and in the inert gas circuit the drum (4) bridging between the drying drum (4) and pre-separator and cooler (5) is returned. 8. The device according to claim 7, characterized in that starting from the fan (7) both in the inert gas circuit (18 to 23) in front of the heat exchanger (8) and before the branching of a short-circuit line (27) and in the branching partial circuit ( 43) a controllable shut-off device (25, 51) is arranged. 9. The device according to claim 7 and 8, characterized in that in the partial circuit (43 to 47) of the inert gas to protect the dried coal, a mixer (38), a weighing device (37) and an intermediate silo (36) are included. 10. The device according to claim 5, characterized in that the lockable supply line (30) for water or water vapor at the entrance to the drying drum (4) is connected to the inert gas circuit. 11. The device according to claim 5, characterized in that the lockable supply line (32) for air between the cloth filter dedusting (6) and fan (7) is connected to the inert gas circuit. 12. The apparatus according to claim 5 and 6, characterized in that the heat exchanger (8) connected to the inert gas circuit (18 to 23) is on the other hand connected to a heating circuit (9) which has an exhaust gas recirculation (11) in which a controllable shut-off device (13) is provided. 13. The apparatus according to claim 12, characterized in that a further heat exchanger is provided, through which on the one hand the or part of the exhaust gases from the heating circuit (9) which are not returned via the exhaust gas recirculation (11) are guided and on the other hand a further circuit of a heat transfer medium , in particular that of the thermal oil for heating the binder tank (40) is connected.

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