WO2011057601A1

WO2011057601A1 - Co2 removal from flue gases by chemical scrubbing and heat integration with coal drying and device for performing the method

Info

Publication number: WO2011057601A1
Application number: PCT/DE2010/001284
Authority: WO
Inventors: Jewgeni Nazarko; Sebastian Schiebahn; Ernst Riensche; Ludger Blum; Detlef Stolten
Original assignee: Forschungszentrum Jülich GmbH
Priority date: 2009-11-16
Filing date: 2010-11-03
Publication date: 2011-05-19
Also published as: DE102009053009A1

Abstract

The invention relates to a method for removing carbon dioxide from a flue gas, comprising the steps: - the flue gas (a) is fed to an absorption unit (1), in which at least part of the CO₂ is absorbed from the flue gas by means of a liquid absorbent (d) fed to the absorption unit, - the liquid absorbent (c) enriched with CO₂ is fed to a desorption unit (2) and heated, wherein at least a part of the CO₂ is released from the absorbent, - the released CO₂ is discharged (e) from the desorption unit together with the portion of absorbent evaporated in the desorption unit, and fed to a gas/liquid separating unit (3a), - in the gas/liquid separating unit, the gaseous CO₂ is separated (g) from the absorbent that has been condensed out. The method according to the invention is characterized in that the released CO₂ is first fed (4) from the desorption unit to a coal drying unit as a heat-transfer medium (e) together with the portion of absorbent evaporated in the desorption unit before the released CO₂ is fed to the gas/liquid separating unit.

Description

description

CO 2 EXTRACTION FROM SMOKE GASES BY CHEMICAL WASHING AND HEAT INTEGRATION WITH COOL DRYING AND DEVICE FOR CARRYING OUT THE PROCESS

The invention relates to a method for C0 ₂ separation from power plant exhaust gases (flue gases) by means of a chemical wash, and a device for carrying out the method, in particular an adsorption desorption plant. State of the art

The combustion of lignite, due to its elemental composition, leads to high mass specific C0 ₂ emissions. Therefore, it is attempted to separate the resulting from the combustion of carbonaceous fuels C0 ₂ and then store it in order not to let it go into the atmosphere. The reason for this effort is the greenhouse effect and the resulting global warming.

There are currently three principal concepts of carbon dioxide capture that differ in the positioning of the separation in the energy conversion process. These are the C0 ₂ separation before the energy conversion (pre-combustion), the production of a C0 ₂ - rich flue gas through the energy conversion in an enriched oxygen atmosphere (Oxy-Fuel), and the C0 ₂ separation after energy conversion (post-combustion ).

The concept of C0 ₂ separation after energy conversion has the end-of-pipe problem solving the advantages that the C0 ₂ separation itself has only a minor impact on the availability of the energy conversion plant, and given the opportunity to retrofit existing facilities , In most power plants, the flue gas leaves the chimney, with the C0 ₂ , accounting for about 15% by volume (depending on the power plant, fuel, firing conditions, etc.), released into the atmosphere.

For the separation of C0 ₂ from flue gas various methods are used, for example, the chemical or physical absorption in absorption towers or in membrane contactors or a C0 ₂ -selective membrane.

The C0 ₂ wash as chemical absorption (CAS = Chemical Absorption System) functions. as follows. The flue gas is passed through a washing liquid after denitrification and desulfurization and possibly further cooling. This liquid usually contains amines. The C0 ₂ can first be bound chemically or physically in the detergent (absorption). The entire cleaning liquid is then heated, whereby the C0 ₂ separates again from the amines (desorption). The washed-out C0 ₂ is almost pure and can then be compressed and possibly transported away to a storage. The amine-containing washing liquid is reusable after heating. For low to moderate C0 ₂ partial pressures, a separation of 75 to 90% can be achieved. The regeneration of the detergent, however, is an energy-consuming process, since the exothermic reaction detergent C0 ₂ is reversed by supplying heat. The required heat, which is taken from the power plant process, usually has a detrimental effect on the power plant efficiency. The enriched with C0 ₂ raw gas usually enters from below into the absorber and flows through it to the top. Clean, C0 ₂ -depleted detergent (absorbent) is added to the absorption column over the beds and trickles down in countercurrent to the gas. During intensive contact between gas and detergent in the beds, the detergent loads in the direction of the thermodynamic equilibrium with the C0 ₂ to be washed out of the gas, so that the flue gas leaves the wash column with a reduced C0 ₂ content, whereas the detergent is enriched with C0 ₂ ,

It must be freed of its C0 ₂ charge before being used again as a C0 ₂ -fatty leaching detergent. The regeneration of the detergent preferably takes place at elevated temperature, so that, for reasons of energy optimization, a first heat exchanger heats the laden detergent and simultaneously cools the warm, regenerated and thus again C0 ₂ -depleted detergent. Further heating of the absorbent can take place either in a heater before the desorber or in another apparatus which is located at the bottom of the regenerating. The heated detergent trickles down in the desorber over the bed, whereby a part of the C0 ₂ goes back into the gas phase and rises in the desorber upwards.

At the head of the desorber, the gaseous C0 ₂ is cooled by a further heat exchanger, with evaporated detergent condensed out and via a line in the Desorption is returned. If necessary, water introduced into the process with the raw gas can also be discharged here.

Alternatively or additionally, desorption can be carried out by lowering the pressure with the aid of a vacuum pump arranged at the head of the desorber.

The C0 ₂ -depleted detergent from the bottom of the regeneration column can now be reloaded in the absorber. For this purpose, it is to cool to absorber temperature, which is used in addition to the detergent countercurrent usually a second heat exchanger with cooling water.

Depending on the binding forces between the transition component and the absorption liquid act, one speaks of physical or chemical detergents. Liquids in which both types of binding occur in relevant order of magnitude are called hybrid detergents.

So far, detergents, in particular amine-based solvents are known, for example, diethanolamine, triethanolamine, activated methyldiethanolamine and monoethanol amine. Mono-ethanol-amine (MEA) is known to require a high desorption temperature of about 120 to 130 ° C due to the strong binding effect between C0 ₂ and MEA. This energy requirement must be additionally made available by the power plant, thus adversely reducing the efficiency by about 1 to 13 percentage points.

On a pilot plant scale, alternative detergents are currently being investigated that would require less regeneration energy due to their lower heat capacity and / or lower absorption enthalpy. The Technical University of Dresden, for example, is testing the detergent GenosorbN, which according to the current state of affairs suggests a significant energy saving. State of the art lignite drying

The brown coal contains up to 60% by weight of water. For the evaporation of the water contained in the coal 15 to 20 wt .-% of the fuel quantity are necessary in the conventional lignite power plants depending on the water content of lignite. Therefore, this fuel quantity of steam generation and thus the power generation is no longer available. The lignite was also to be dried for the application of C0 ₂ separation (regardless of the deposition concept).

Currently, the lignite is dried with hot flue gases at a temperature of 900 to 1000 ° C, the flue gases are withdrawn from the furnace. However, in order to increase the efficiency of the lignite-fired power plants, it would be advantageous to dry the lignite at a lower temperature level.

Various drying and dewatering processes have already been developed for use in power plants, such as the fluidized-bed dryer, in which the coal water evaporates as it passes through the fluidized bed. In the drying processes currently under development, the energy required for drying is usually provided by a steam-heated heat exchanger. In addition to heating steam at 10 to 12 bar, alternatively and preferably, heating steam can also be taken from a low-pressure turbine at only about 3 bar, which is available at about 133 ° C. for drying the brown coal. The drying takes place at a pressure of about 1, 1 bar and at a fluidized bed temperature of about 1 10 ° C in almost pure steam atmosphere.

Part of the heat of the evaporated water from lignite can be recovered by using the vapors (water vapor from lignite drying) either for boiler feed water pre-heating or also for heating lignite coal drying. In the first case described, steam extraction from the steam power process is necessary for coal drying. In the second part described, the vapors for coal drying must be recompressed with a compressor so that a temperature difference between the vapors to be cooled and the water to be evaporated from the brown coal is given. Despite the heat recovery lignite drying is an energy-consuming process due to the steam extraction or due to the repeated compression of the vapors. Task and solution

The object of the invention is to provide a further method for the effective reduction of C0 ₂ emissions from the exhaust gases of combustion plants, which is overall more energy efficient and thus cheaper than before.

Furthermore, it is the object of the invention to provide a suitable device for carrying out the aforementioned method.

The objects of the invention are achieved by a method according to the main claim and by a device with the entirety of the features of the independent claim. Advantageous embodiments are shown in the respective dependent claims.

Subject of the invention

The invention relates to a combined method for reducing C0 ₂ emissions from the exhaust gases of combustion plants, in particular from flue gases of energy conversion plants, with an integrated coal drying, especially a lignite drying. Furthermore, the invention relates to a device suitable for carrying out this method.

In the following, the term firing plant is understood to mean any plant in which a gaseous, liquid and / or solid fuel is oxidized to utilize the heat generated. These include, for example, gas burners, which are operated with natural gas, liquefied petroleum gas, city gas or landfill gas, oil burners, the z. B. with petroleum, fuel oil, or alcohols are operated, and also grate firing for particulate fuels, such as gas-rich coal or woodchips, fluidized bed or dust firing.

Flue gas is the gaseous combustion product produced during the technical combustion of fuels. Flue gases usually include solid, liquid and / or gaseous impurities such as nitrogen, carbon dioxide, sulfur dioxide, nitrogen oxide and water vapor as gases, solid particles such as fly ash and soot, and optionally also carbon monoxide or hydrogen.

The idea of the invention is based on an improved over the prior art and To provide more effective C0 ₂ separation from a flue gas by means of chemical absorption, in which a coal drying is integrated to the more effective energy yield of this process and taking advantage of synergistic effects. For this purpose, a cooling step required in the CO ₂ removal from a flue gas is advantageously used to dry coal, in particular moist brown coal, at least in part.

According to the invention, the CO ₂ separation takes place from the flue gas by means of chemical scrubbing. After chemical (or physical) C0 ₂ binding in a suitable detergent (absorbent), the C0 ₂ -rich wash solution is passed into a desorption column. By heating the C0 ₂ -rich wash solution, the absorbed C0 _{2 is} expelled from the wash solution. The heating of the washing solution can be effected, for example, by a heat exchanger operated with low-pressure steam taken from the turbines. As a rule, part of the washing solution, in particular water, is evaporated together with C0 ₂ . The amount of the evaporated wash solution varies depending on the operating conditions of the process, in particular temperature, pressure, C0 ₂ loading of the wash solution. As washing solutions, in particular amine-based liquids are suitable. For the separation of the C0 ₂ from the evaporated washing solution a cooling and a subsequent gas / liquid separation are provided regularly. The previous cooling is required so far as the most effective separation, in other words a pure C0 ₂ stream, is sought. The lower the temperature selected during the gas / liquid separation, the more completely the previously evaporated wash solution can condense out again.

The idea underlying the invention is now, instead of or at least in addition to this cooling provided so far, which is usually accomplished with a coolant to integrate a further heat-absorbing process, in particular to integrate at this point a coal drying. Coal drying, especially when drying moist brown coal, requires energy in the form of heat. According to the teaching of the invention, the gaseous, released C0 ₂ together with the evaporated in the desorption unit absorbent (washing solution) at the top of Desorpti- on unit (column head) withdrawn and a coal drying unit, in particular a lignite drying unit supplied. The released C0 ₂ and the vaporized absorbent often have an overpressure on leaving the desorption unit. typical see pressure conditions are between 1 and 8 bar, in particular between 2 and 6 bar. The temperatures required for desorption (release) of C0 ₂ from the absorbent are generally well above 100 ° C. for amine-based wash solutions. Accordingly, the released C0 ₂ together with the proportion of absorbent evaporated in the desorption unit when leaving the desorption unit usually has temperatures of more than 100 ° C, in particular more than 120 ° C, and advantageously more than 130 ° C.

This heated and possibly pressurized mixture is advantageously suitable to be used as a heat transfer agent for the process of coal drying. For this purpose, the invention provides, the released C0 ₂ together with the vaporized in the desorption unit of absorbent, which is discharged from the desorption unit, direct to a coal drying unit to be used there at least for partial drying of the coal. Advantageously, this mixture acts as a medium for a heat exchanger, which is arranged in the coal drying. For example, this heat exchanger fed by the mixture is placed directly in the fluidized bed of a fluidized bed dryer of a coal drying unit. In addition, other heat exchangers, for example, with steam-operated heat exchangers, as previously customary be arranged within the coal drying unit. The condensation of the evaporated washing solution takes place at a corresponding pressure regularly at a temperature which is above the temperature of the coal drying, so that the water contained in the coal at least partially evaporated.

Nevertheless, during the heat transfer to the coal to be dried, at least some condensation of the vaporized absorbent may already occur.

The actual separation of the gaseous C0 ₂ from the absorbent is carried out regularly in the downstream gas / liquid separation unit. The lower the temperatures in the gas / liquid separation unit, the better the degree of separation. Depending on the conditions, the mixture can be fed directly to the gas / liquid separation unit after passing through the coal drying unit, or, if necessary, also be further cooled before.

The condensed wash solution from the heat exchanger is separated after passing through the coal dryer from C0 ₂ -rich gas stream and for washing solution treatment recycled. If necessary, the washing solution can be prepared beforehand and, if appropriate, appropriately tempered via a further heat exchanger.

The evaporated water from the coal drying (vapors) can be used as before for the supply of gas, district heating or for another purpose. Part of the resulting water vapor can be used for direct turbulence of the brown coal to be dried and for the production of the floating fluidized bed or in addition as a heat exchanger to support the brown coal drying process. In addition to this advantageous embodiment of the invention, it is also conceivable in principle, auszuschleusen the heat for lignite drying at another point from the adsorption / desorption process, for example by the heated regenerated wash solution is first used for lignite drying before they preheat with C0 _2- loaded wash water before the desorption column is used.

The advantage of the invention is that a large part of the energy for coal drying, in particular completely or in part by waste heat from the C0 ₂ may be provided -Redu- zierungsprozess, in particular by the heat for the de- sorption of C0 ₂ from the loaded wash water is needed. Due to the condensation of the evaporated washing solution outside the desorption column, it is advantageously possible to cover the energy required for drying the coal at least partially. As a result, on the one hand eliminates the amount of cooling water to cool the wash solution or at least reduced, and on the other hand, less energy from other processes, in particular in the form of steam from the turbine to be decoupled for drying the lignite. In total, this leads to a significant increase in power plant efficiency.

Special description part

In the following, the invention will be explained in more detail with reference to exemplary embodiments, without this limiting the scope of protection. The person skilled in the art can readily recognize analogous modifications in these as belonging to the invention.

In this case, in FIGS. 1 to 4:

a C0 ₂ -containing flue gas,

b C0 ₂ -depleted offgas, c with C0 ₂ -enriched washing liquid (absorbent),

d regenerated, C0 ₂ -depleted washing liquid,

e evaporated washing liquid with C0 ₂ ,

f condensed washing liquid with C0 ₂

g separated, gaseous C0 ₂

H condensed and separated from the gaseous C0 ₂ washing liquid

i wet raw lignite

dried lignite

k steam

1 condensate

m vapors

n vapor condensate

absorbing unit

2 desorption unit

3a, 3b separation unit gaseous / liquid

4 coal drying unit

WT1 - WT7 heat exchanger

1 shows the diagram of an energy conversion process, here an energy production in a coal power plant with the C0 ₂ separation from the flue gas (decarbonization) by means of chemical scrubbing (eg 30% aqueous solution of the monoethanolamine) after the flue gas cleaning according to FIG the current state of the art. The flue gas cleaning of a fired with a solid fuel and the current state of the art large combustion plant includes the denitrification, dedusting and desulfurization in this order. The chemical washing separates 90% of the CO ₂ contained in the flue gas (a) with a purity of 99% by volume (g). Due to the regeneration of the washing solution and the electrical consumption of the decarburisa- tion plant, the power plant net efficiency is reduced by 10 percentage points in a defined design case.

From a ton of raw lignite with a water content of 60 wt .-% and a carbon content of 68.3 wt .-% water-and-ash-free about 974.686 kg C0 _{2 are} released. At a specific energy requirement of 4 MJ / kg C0 ₂ , approx. 3,898 GJ of heat needed. Subsequently, this heat is then removed in the warmed and evaporated wash solution together with the liberated C0 ₂ via heat exchanger for cooling the wash solution for reuse and for the purpose of concentration of C0 ₂ .

In detail, FIG. 1 shows a washing process from the prior art. The raw flue gas (a) loaded with C0 _{2 is} fed to an absorption unit (1), which flows through it from bottom to top. Here it applies to the washing solution (d) (absorbent), often an aqueous solution of amines, which is added to the head of the absorption unit (1) and receives in countercurrent C0 ₂ from the flue gas. The C0 ₂ -saturated wash solution (c) is passed into a desorption unit (2), where it is heated to about 120 ° C (WT1). At these temperatures, the C0 ₂ (desorbed) dissolves again from the wash solution. The liberated C0 ₂ is removed together with the evaporated washing solution (e) from the desorption unit (2) and cooled (WT4). The separated in a gas / liquid separation unit (3a) C0 ₂ (g) is now present in high purity, while the separated condensed wash solution (h) is returned to the desorption unit (2). The scrubbing solution freed of C0 ₂ in the desorption unit (2) is cooled (WT1, WT2) and returned to the absorption unit (1) where the washing process starts again. FIG. 2 shows the scheme of a brown coal drying process with vapor condensation from the prior art. The wet coal (i) is fed to a coal drying unit (4). A heat exchanger operated with steam (k) provides the heat transfer required for the drying of the wet coal, so that it can be withdrawn, mainly dried, from the coal drying unit (4) as dried coal (j). The steam already partially condenses in this process (1). Part of the vapors (m) is used to fluidize the fluidized bed in the coal drying unit (4), another part after cooling (WT5) condensed (n). For a brown coal with the water content of 60% by weight, a coal temperature of 1100C and residual water content in the dry lignite of 12% by weight, about 205 MJ will have to be spent on coal heating and about 1.245 GJ on coal drying ,

In the case of the lignite drying process with vapor recompression, which is also known from the prior art, and illustrated in FIG. 3, approximately 1 10 MW of electrical energy is used for the recompression of vapors (552 kg) from one ton of raw lignite from 1 to 2.5 bar. In this version, the heat of the vapors is used after compression as a heat exchanger for coal drying.

FIG. 4 shows the diagram of an energy conversion process with the combined method according to the invention for reducing C0 ₂ emissions from flue gases of energy conversion plants with integrated coal drying.

After possibly denitrification, dedusting, desulfurization and possibly further cooling, the flue gas (a) of the absorption unit (1) is supplied. There, the C0 ₂ by means of the washing solution (d) washed out of the C0 ₂ -containing flue gas (a). The C0 ₂ depleted flue gas (b) leaves the absorption column (1). The C0 ₂ enriched wash solution (c) passes after preheating via a heat exchanger (WT1) in the desorption unit (2), where the C0 ₂ is released under heating. The liberated gaseous C0 ₂ and the evaporated washing solution (e) together leave the desorption column (2) with an overpressure, and are fed to a heat exchanger (WT6) a coal drying unit (4). The condensation of the evaporated washing solution takes place regularly at a temperature which is above the temperature of the coal drying, so that the water contained in the coal evaporates as vapors (m). The scrubbing solution freed from C0 ₂ leaves the desorption unit (2), is cooled (WT1 and optionally WT2) and returned to the absorption unit (1).

After passing through the heat exchanger (WT6) in the coal drying unit (4), there may already be an at least partially condensed scrubbing solution and a C0 ₂ -rich gas stream (f), which subsequently in a gas / liquid separation unit (3a) into a liquid Washing solution (h) and a gaseous C0 ₂ phase (g) is separated.

There are two alternatives available for this, which can also be used cumulatively if necessary. In a first embodiment of the invention, the CO ₂ leaving the coal drying unit is supplied directly to a gas / liquid separation unit (3a) together with the washing solution evaporated in the desorption unit (2). There, the separated condensate of the washing solution (h) is fed directly back to the desorption unit (2). The separated C0 ₂ -rich gas stream (g) is fed to a further treatment. The gas / liquid separation takes place this takes place without further cooling of the mixture at a high temperature level. The separated under these conditions C0 ₂ disadvantageously still has a significant proportion of water. However, the separated washing solution still has such a high temperature level that it can be returned directly to the desorption unit.

In a further alternative, the CO ₂ leaving the coal drying unit is first cooled (WT 7) together with the scrubbing solution evaporated in the desorption unit (2) and only then supplied to a gas / liquid separation unit (3b). The gas / liquid separation is carried out in such a way that the proportion of water still present in the separated C0 ₂ - stream can be significantly lowered. However, the condensed wash solution now has such low temperatures that a direct use in the desorption unit makes little sense energetically. Therefore, in this case, the washing solution is fed directly or through further cooling (WT2) to the absorption unit (1). Depending on the framework conditions and circulation of the washing solution, a procedure may also be advantageous in which both paths indicated above are taken simultaneously. By a control, the proportions for a direct return to the desorption unit or to the absorption unit could advantageously be regulated directly as required. The evaporated water from the coal drying (vapors) can be used for feedwater pre-heating, district heating or for another purpose. After the heat release the vapor condensate is optionally fed to the water treatment. Part of the resulting water vapor can be used as in the prior art for turbulence of the brown coal to be dried and for the production of the floating fluidized bed.

When using the waste heat from the washing unit according to the invention in the drying of coal can be advantageous to dispense with the removal of the steam for drying coal completely or partially, or the energy-consuming recompression of the vapors are saved.

In particular, the use of lignite dried by this type in the power plant process, an efficiency gain of up to 4% points can be achieved. Taking into account the losses from the C0 ₂ separation results in a loss of efficiency of only 6 percentage points for the entire process.

Claims

claims

1. A method for separating carbon dioxide from a flue gas with the steps

- the flue gas is fed to an absorption unit, in which at least a part of the C0 ₂ fed from the flue gas by means of a liquid of the absorption unit is Abso tion means absorbs,

the liquid absorbent enriched in C0 ₂ is fed to a desorption unit and heated, at least part of the CO _{2 being released} from the absorbent,

the released C0 ₂ is discharged from the desorption unit together with the fraction of absorbent evaporated in the desorption unit, and fed to a gas / liquid separation unit,

in the gas / liquid separation unit, the gaseous C0 _{2 is separated} from the condensed absorbent,

characterized in that

the liberated C0 _{2 is} first supplied together with the evaporated in the desorption unit portion of absorbent from the desorption as a heat transfer medium a coal drying unit before it is fed to the gas / liquid separation unit.

2. The method of claim 1, wherein in the coal drying unit lignite is dried.

3. The method of claim 1 to 2, wherein the separated C0 _{2 is} fed together with the vaporized in the desorption unit absorbent to a heat exchanger within the coal drying unit, and heat is delivered to the coal to be dried.

4. The method of claim 1 to 3, wherein the vaporized absorbent condenses at least partially by the heat in the coal drying unit.

5. The method of claim 1 to 4, wherein the liberated C0 _{2 is} discharged together with the vaporized in the desorption unit portion of absorbent under pressure from the desorption.

The method of claim 1 to 5, wherein the released C0 ₂ together with the vaporized in the desorption unit of absorbent on leaving the desorption has a pressure between 1 and 8 bar, in particular between 2 and 6 bar.

The method of claim 1 to 6, wherein the released C0 ₂ together with the vaporized in the desorption unit of absorbent on leaving the desorption unit temperatures of more than 100 ° C, in particular more than 120 ° C, and advantageously more than 130 ° C. ,

8. The method of claim 1 to 7, wherein the released C0 _{2 is} fed together with the vaporized in the desorption unit of absorbent after leaving the coal drying unit directly to a gas / liquid separation unit, and there separated absorbent is returned to the desorption.

9. The method of claim 1 to 7, wherein the liberated C0 _{2 is} first further cooled together with the evaporated in the desorption of absorbent after leaving the coal drying unit, a

Gas / liquid separation unit is supplied, and the separated there absorption medium is supplied to the absorption unit.

10. The method of claim 1 to 7, wherein the liberated C0 ₂ together with the vaporized in the desorption unit of absorbent after leaving the coal drying unit is both partially fed directly to a gas / liquid separation unit, and the separated there absorbent is returned to the desorption , as well as partially partially cooled further, one

A device for separating carbon dioxide from a flue gas with an absorber unit (1) in which flue gas is contacted with absorbent, and with a desorption unit (2), is released in the C0 ₂ from the heated C0 ₂ enriched absorbent a recirculating circuit (c, d) for an absorbent between the absorption unit (1) and the desorption unit (2), and another vaporized adsorbent conduit together with liberated C0 ₂ (e) from the desorption unit (2) to a gas / liquid separation unit (3a, 3b), characterized,

in that the line between the desorption unit (2) and the gas / liquid separation unit (3a, 3b) is at least partially formed as a heat exchanger (WT6) for a coal drying unit (4).

12. The apparatus of claim 1 1, wherein the coal drying unit is integrated in this device.

13. The apparatus of claim 1 1 to 12, with a lignite drying unit.

14. The apparatus of claim 1 1 to 13, with a line for auskondensiertes absorbent (h) from the gas / liquid separation unit (3a) to the desorption unit (2).

15. The apparatus of claim 1 1 to 13, with a line for auskondensiertes absorbent (h) from the gas / liquid separation unit (3 b) to the absorption unit (2) and with a gas / liquid separation unit upstream further heat exchanger (WT7).

16. The apparatus of claim 11 to 13, comprising a line for condensed absorbent (h) from a first gas / liquid separation unit (3a) to the desorption (2) and with a line for condensed absorbent (h) from another gas / liquid separation unit (3b ) to the absorption unit (2) and to a further heat exchanger (WT7) connected upstream of the further gas / liquid separation unit (3b).