WO2008095984A2 - Method and device for the combustion of solid fuels - Google Patents

Abstract

The invention relates to a method and a device for the combustion of solid fuels using combustion agents containing free oxygen, in particular for an oxyfuel process. According to said method, gases that are charged with dust in the form of fine ash and grit exit the combustion chamber at the top and predominantly coarse-grained products exit the combustion chamber as bottoms, the combustion chamber being supplied with the combustion agents required for complete combustion. The method is carried out in such a way that the combustion chamber is divided into at least one first combustion zone, designed as a moving bed and at least one second combustion zone, located above the first and designed as a highly expanded or circulating fluidised bed, that the division of the combustion chamber is achieved by at least one lateral injection of second combustion agents required for the extensive combustion of the solid fuels, said injection being directed towards the centre of the combustion chamber and the second combustion agents having an oxygen content > 50 % by volume and being injected at a speed > 10 m/s to 100 m/s, that the first combustion agents required for almost complete combustion are injected in a counter-current at the lower end of the first combustion zone, the oxygen content of the gas mixture being restricted to < 50 %, preferably < 21 % to < 10 %, and that the solid fuels are introduced into the combustion chamber to a depth beyond the upper end of the first combustion zone sufficient to prevent the formation of hot-spots at the level of the introduced material and in the area surrounding the latter, in which hot-spots most or all of the ash melts.

Description

 Process and apparatus for burning solid fuels

The invention relates to a method and a device for burning solid fuels with combustion agents containing free oxygen, in particular for an oxyfuel process.

In the oxyfuel process, the combustion of a carbonaceous fuel produces a nearly pure CO ₂ gas. The aim is to convert the chemically combined heat of the fuel (calorific value) completely into sensible heat, which is used in the steam-power process to generate electrical energy. The combustion of the fuel takes place in a dust firing with supply of nitrogen-reduced combustion air (high concentration of oxygen).

When using the method, a subsequent CO ₂ separation is desired in order to continue to use, store or deposit it. Due to the elimination of N ₂ from the combustion air, there is a high CO ₂ partial pressure in the flue gas after combustion. This is for the separation of most contaminants from the flue gas advantage. The water produced by the combustion can easily be condensed out.

The oxyfuel process is operated at temperatures below the ash melting temperature. To ensure this, very large quantities of flue gas must recirculate dust-free in the process. Furthermore, there is the disadvantage that the ash still contains unburned carbon and on the other hand is not available as recyclable material available. For this purpose, DE 10 2004 059 360 proposes a "process for burning fossil fuel in power plants operating according to the oxyfuel process", which is characterized in that a known melting chamber furnace is used as the furnace, the furnace being designed in this way and operated at such temperatures that at least a portion of the ash is molten and discharged in this state from the furnace.

The said known solutions provide the combustion in dust firing with dry and wet deashing. Both solutions have the disadvantage of a complex CO ₂ -Rezirkulation, although reduced in the Schmelzkammerfeuerung, but still is significant. Therefore, the disadvantages of the high system complexity for the Rezirkulationswämetauscher, the high operating costs and self-consumption of Rezirkulationsverdichters, the complication of the process and thus inferior operational flexibility (load cycling), the increased corrosion and tendency to formation due to carbonate formation, the efficiency losses (Exergieverluste), in particular by the warm-up and cooling the large CO 2 mass flow.

From the gasification technology methods are further known in which carbonaceous fuels are partially oxidized with oxygen-containing gasification agents, carbon monoxide (CO) and hydrogen (H ₂ ) are formed as target products. Only to a lesser extent does CO ₂ accumulate. The release of sensible heat is typically only about 20 to 30% of the heat that is released in oxyfuel processes. The reaction conditions and the ongoing chemical reactions in the gasification technology are fundamentally different from those of combustion technology. In gasification processes, reactions of the gas phase dominate with CO and H ₂ , whereas in combustion processes the reactions with free oxygen dominate.

As an example of gasification processes, the practically performed and known from the literature HTW gasification process called. This is a fluidized bed gasification process. In the HTW gasification process, a dust circulation takes place via a cyclone, with particulate matter being discharged from the system above and not being recirculated. In a patent pending process for the gasification of carbonaceous solids in the fluidized bed and a suitable carburetor (EP 1 201 731 Al), all the fluidized bed leaving the top dust within the carburetor deposited with a suitable filter. The deposition takes place in a cooling zone arranged downstream of the fluidized bed zone in the direction of flow of the gas, in which cooling of the dust-laden raw gas and the removal of heat continue to take place. Subsequently, the dust is returned to the fluidized bed zone of the carburetor.

The theory of partial oxidation known from gasification basically gives the expert no indication as to how to make the complete oxidation of solid fuels under the condition of the extensive to complete conversion of the carbon of the solid fuels to CO ₂ . The object of the invention is to achieve a reduction or avoidance of the flue gas recirculation in processes for the combustion of solid fuels with free oxygen-containing combustion agents and thereby plant and operational simplifications and to increase the efficiencies and reduce consumption.

According to the invention, the object is achieved by a method for burning solid fuels with free oxygen-containing combustion agents in the dust with dust, in the form of particulate matter and grit laden gases leave the combustion chamber on the top side and predominantly coarse-grained products the combustion chamber as a bottom product on the underside, wherein the combustion chamber the combustion medium necessary for the complete combustion, and characterized in that the combustion chamber is separated into at least one first combustion zone, which is designed as a moving bed, and at least one second combustion zone located above, which formed as a strongly expanded or circulating fluidized bed is that the separation of the combustion chamber by at least one lateral, directed into the middle of the combustion chamber injection of the required for the extensive combustion of the solid fuels second Verb With the second combustion agent having an oxygen content> 50 Vo 1 .-% and are injected at a speed of> 10 m / s to 100 m / s, that at the lower end of the first combustion zone required for the virtually complete combustion first Burning in countercurrent be blown, wherein the oxygen content of the gas mixture is limited to <50%, preferably <21% to <10%, and that the solid fuels are registered so far above the upper end of the first combustion zone in the combustion chamber, that in Height of the entry and its surroundings do not form hot spot zones in which ash melts predominantly or completely. The environment extends to a radius around the entry of max. about 1 m. Within this radius, experience has shown that slagging preferably occurs because, due to the high carbon contents, excessive temperature excesses to values above the ash softening temperatures can occur particularly quickly here.

The combustion means, ie the first and / or the second combustion means may contain, in addition to oxygen, carbon dioxide, water vapor, NH 3 and / or purge gases. These secondary constituents can be oxidized substantially free of pollutants at the temperatures and oxygen concentrations occurring in the process according to the invention (NH ₃ , purge). Gases) or used to control the combustion processes (carbon dioxide, water vapor).

The combustion process takes place advantageously in a top-cylindrical and bottom-cylindrical or conically narrowing combustion chamber open on both sides. However, the combustion chamber can also have a square or rectangular flow cross-section. The combustion chamber is subdivided into at least one first combustion zone, whereby it is designed as a moving bed, and into at least one second combustion zone situated above it, this being constructed as a strongly expanded or circulating fluidized bed.

The separation of the combustion chamber is effected by at least one lateral, directed into the middle of the combustion chamber injection of the required for the extensive combustion of the solid fuel predominantly free oxygen-containing second combustion agent. The injection angle is 20 ° to 100 °, preferably 45 ° to 90 °. The injection angle .alpha..sub.i is the angle between the injection device (generally its geometric axis) and the inner contour of the combustion chamber seen from the vertex of the angle. In smaller apparatus, the injection of the second combustion agent takes place with a, compared with larger apparatuses, more obtuse injection angle, so that the opposite inner surface of the combustion chamber jacket is not illuminated with free oxygen.

The fuels are introduced above the top of the first combustion zone into the combustion chamber, especially into the second combustion zone. The entry is so far above that there is an intensive turbulence and combustion of the fuels with the rising gases of the first and second combustion means. Preferably, the fuels are introduced at a distance of 1 m to 10 m, more preferably at a distance of 2 m to 5 m, above the upper end of the first combustion zone in the combustion chamber. The supply of solid fuels takes place at an entry angle of 90 ° to 180 °, preferably from 100 ° to 160 °. The entry angle α ₂ is the angle between fuel input (in general its geometric axis) and the inner contour of the combustion chamber seen from the vertex of the angle downwards. An approximately right angle, to the inner contour of the combustion chamber, favors little Appa- rate overall heights. For entry of solid fuels with poor flow behavior, a blunt to elongated angle is advantageous.

The supply of the solid fuels may take place at the predetermined distance above the upper end of the first combustion zone at different heights and distributed over the circumference of the combustion chamber jacket.

The extensive combustion of the solid fuels takes place in the second combustion zone. The strong fluidization is required to evenly distribute the carbon in the second combustion zone. The uniform distribution is a prerequisite for the formation of so - called hot spot zones in the fluidized bed, in which the ash melts predominantly or completely, and as a consequence, disruptive slagging may occur.

The supply of the second combustion means takes place at a high injection rate, since the combustion medium is oxygen predominant fluidizing agent and the oxygen of the second combustion agent is also to reach the center of the combustion chamber of the second combustion zone. The injection rate of the second combustion medium is over 10 m / s for small plants and up to 100 m / s for large plants.

The conversion of the carbonaceous solid fuel in the second combustion zone is carried out at temperatures between 750 ⁰ C and 950 ⁰ C, which locally in the areas in which oxygen-containing second combustion agent is injected, higher temperatures may occur, so that, depending on the melting point of the ash the solid fuels may be granulated at least a portion of the ash constituents. These requirements can z. B. be present when burning Rhenish lignite whose ash has a melting point of 1,250 ⁰ C.

At the lower end of the combustion chamber, the ash discharge and the supply of the required for the virtually complete combustion of carbon amount of first combustion agent, wherein the oxygen further gases (for example, CO ₂ , H ₂ O, etc.) are admixed and the oxygen content of the gas mixture <50%, preferably <21% to <10%. The first combustion means are used for the most complete possible combustion of the remaining carbonaceous constituents and for the oxidation of the ashes in a first combustion zone, this being designed as a moving bed.

The first combustion means may be injected in a plurality of superimposed regions and / or at the lower end of the first combustion zone. If necessary, it is possible to inject first combustion agents of different composition, for example consisting of water, (V vapor, O 2 / CO 2 and VCC vapor mixtures in the individual planes.) The use of different first combustion agents at different heights in the first combustion zone may occur show that on the one hand a most extensive implementation of carbon-containing residues and possibly also an oxidation of the ash or granules to take place, on the other hand, however, the temperature is kept below the ash melting point and an end product is to be discharged from the first combustion zone, which cooled as far is that it can be handled with the usual means of transport, equipment, etc. Thus, the composition and amount of the first combustion agent are adjusted so that the carbon content of the first combustion zones at the lower end of the Verbrennungsr Aumes leaving bottom product is reduced to the values required for landfilling. Furthermore, the final residue, which consists essentially of ash and ash granules, is to be cooled before it leaves the lower end of the first combustion zones of the combustion chamber.

The rate at which the carbonaceous ingredients, ashes and ash granules, e.g. B. by means of a screw conveyor, are discharged from the lower end of the first combustion zones of the combustion chamber is essentially determined by the residence time of the solids and dusts in the combustion chamber, which is required at the given conditions, in particular temperatures, to the desired carbon conversion to reach.

In the combustion process according to the invention, solid matter and dust circulate in the combustion chamber, or coarse dust is recirculated via the separator into the second combustion zone. The solid fuels introduced into the upper region of the second combustion zone form larger amounts of dust when incinerated, which is only incompletely separated due to the fineness in the separator. The undeclared particulate matter, usually significantly <1% of the total amount of dust entrained, so it is not returned via the separator, while the coarse dust is recycled through the separator. It is known that fine dust due to its predominantly basic mineral composition (calcium, magnesium, iron, alkalis) in conjunction with the coarser, predominantly acidic ash constituents (quartz and aluminosilicates) favors the formation of low-melting, so-called eutectic, melts. Because of the depletion of fine dust, especially in the field of dust recirculation, especially the recycling of coarse dust, accumulation of the refractory fraction of quartz and aluminosilicate-containing ash constituents occurs. This leads to a significant increase in the softening point of the ash located in the lower region of the second combustion chamber up to 100 K and higher, compared with the softening points of the ashes, in which this separation does not take place. This separation is particularly beneficial for the method according to the invention. In the combustion region in which oxygen is introduced, the melting points of the ashes are thus higher, and consequently the risk of malfunctioning sintering, agglomerations or slagging in this particularly sensitive region of high oxygen concentrations is markedly reduced.

Thus, the inventive method differs from other methods of combustion in the circulating fluidized bed, in which the fuel at the level of the entry of / required for combustion oxygen / air are supplied and fine dust and coarser ash constituents are present side by side and can react with melting point reduction.

As a result of the enrichment of the coarse-grained high-melting ash fraction of the quartz and aluminosilicate ash constituents in the combustion space, the grain spectrum of the solid inventory in the second combustion zone shifts to larger grain diameters. This means that the gas flow velocity can be increased while maintaining the same solids discharges, which increases the specific plant performance.

In the upper part of the combustion chamber, the dust-laden gases are discharged from the combustion chamber. The dust entrained with the gases consists essentially of residual coke with a C content of <2% by mass. In a separator adjoining the upper region of the combustion chamber, a large part of the dust of the gases is separated as coarse dust and fed into the combustion chamber above the combustion agent introduction of the second combustion agent into the second combustion zone. The feed of the separated coarse dust occurs at a distance of 1 m to 10 m, preferably 2 m to 5 m, above the upper end of the first combustion zones. The return of the separated coarse dust is carried out in an entry angle of 90 ° to 180 °, preferably from 100 ° to 160 °. The entry angle Ct ₃ is the angle between coarse dust entry (in general its geometric axis) and the inner contour of the combustion space seen from the vertex of the angle downwards.

The erfmdungsgemäße method ensures that carbon is present with a uniform concentration distribution at a low concentration level in the combustion chamber, mainly with a concentration of <5 Ma. -% to even <2 Ma. -% in the upper and lower part of the second combustion zone.

This represents a great advantage over conventional fluidized bed processes, since the resulting ash discharged from the process has a lower carbon content than conventional fluidized bed processes. The carbon turnover of the combustion process is greatly increased and the carbon loss is reduced.

In order to be able to remove coarse-grained material without interference and to ensure countercurrent complete combustion while supplying first combustion agents, the bottom of the combustion chamber is preferably designed to be open and free of internals.

As solid fuels, biomasses, including sewage sludge, lignite, coal or anthracite and mixtures thereof may be used for the process according to the invention.

Advantages of the inventive method for burning solid fuels with free oxygen contained combustion agents are that

• the disadvantages of the known oxyfuel processes are eliminated by the changed combustion medium and fuel supply as well as combustion chamber design, and at the same time usable ash is obtained,

• the costly CO ₂ -Rezirkulation is greatly reduced, with no high investment outlay for the recirculation heat exchanger, • no high operating costs and no high own consumption of recirculation compressors,

The combustion process is not unnecessarily complicated, whereby a higher operating flexibility (load change behavior) can be obtained,

• there is no increased corrosion, or increased tendency to build up due to carbonate formation,

The efficiency losses (exergy losses) are greatly reduced, in particular by the greatly reduced heating and cooling of the much lower CO ₂ mass flow,

• The carbon conversion rate of the combustion process compared to conventional fluidized bed processes is greatly increased and thus the carbon loss is reduced.

According to the invention the object is achieved by a device for burning solid fuels with free-oxygen-containing combustion agents, which consists essentially of a coolable pressure-resistant reactor housing with a ash discharge at the foot, a combustion gas outlet at the top of the combustion reactor and in which the combustion chamber is separated into at least a first Combustion zone, which is designed as a moving bed, and in at least one second combustion zone located above it, which is designed as a highly expanded or circulating fluidized bed.

The separation of the combustion chamber is carried out by at least one lateral, directed into the middle of the combustion chamber injection device required for the substantial combustion of solid fuels second combustion means. The injection device is designed so that the second combustion agent can be injected with an oxygen content of> 50% by volume and at a rate of> 10 m / s to 100 m / s.

At the lower end of the first combustion zone of the device, a device for injecting the required for the virtually complete combustion first combustion agent with an oxygen content of the gas mixture <50%, preferably <21% to <10%, arranged. The introduction of fuel is arranged so far above the upper end of the first combustion zone that at the level of the entry and its surroundings no hot spot zones are formed in which ash melts predominantly or completely.

The injection device consists essentially of a plurality of nozzles uniformly arranged in a plane on the circumference of the device. The injection angle of the nozzles for the second combustion means is 20 ° to 100 °, preferably 45 ° to 90 °. The injection angle αi is the angle between the injection device (generally its geometric axis) and the inner contour of the combustion chamber seen from the vertex of the angle downwards. In smaller apparatus, the injection of the second combustion agent takes place with a, compared with larger apparatuses, more obtuse injection angle, so that the opposite inner surface of the combustion chamber jacket is not illuminated with free oxygen.

The device for injecting the first combustion agent is advantageously designed such that it permits injection in a plurality of superimposed regions and / or at the lower end of the first combustion zone.

The fuel entry is advantageously designed as a diagonal tube entry. It is oriented so that the supply of solid fuels in an entry angle of 90 ° to 180 °, preferably from 100 ° to 160 °. The entry angle α ₂ is the angle between fuel input (in general its geometric axis) and the inner contour of the combustion chamber seen from the vertex of the angle downwards. An approximately right angle, to the inner contour of the combustion chamber, favored low apparatus heights. For entry of solid fuels with poor flow behavior, a blunt to elongated angle is advantageous.

The fuel entry advantageously consists of several distributed on the circumference of the device in equal or different heights arranged inclined tube entries.

According to an advantageous embodiment of the device according to the invention the combustion gas outlet downstream of a device for dust separation, mainly Grobstaubabtrennung, and recycling the separated coarse dust in the lower part of the second combustion zone. The device for returning the dust, mainly coarse Dust, is arranged so that it allows the return of dust, especially coarse dust, in an entry angle of 90 ° to 180 °, preferably from 100 ° to 160 °. The entry angle Ct ₃ is the angle between coarse dust entry (in general its geometric axis) and the inner contour of the combustion space seen from the vertex of the angle downwards.

An exemplary embodiment of the invention will be explained in more detail with reference to the schematic illustration according to FIG.

The incinerator shown in Figure 1 consists of a combustion chamber (1), which is cylindrical at the top and conically constricted at the bottom, but is open on both sides. The inner diameter of the upper cylindrical portion of the reaction space is 8 m. Half the cone angle is 8 °.

The combustion chamber (1) is subdivided into a first combustion zone (3), which is designed as a moving bed, and a second combustion zone (2) located above it, this being constructed as a circulating fluidized bed. The height of the combustion chamber (1) is 30 m.

The separation of the combustion chamber (1) takes place by a lateral, in the middle of the combustion chamber (1) directed injection of the required for the extensive combustion of the solid fuel predominantly free oxygen second combustion means (4), wherein the second combustion means (4) with a Speed of 20 m / s is injected. The injection angle αi is 60 °. The supply of the second combustion means (4) is effected by 8 evenly arranged in a nozzle plane nozzles. As a second combustion agent (4), the second combustion zone (2) a gas mixture of 90 vol .-% oxygen and 10 vol .-% carbon dioxide at a temperature of 200 ⁰ C is supplied.

The thermal output of the incinerator is 250 MW (th). As a solid fuel (5) comes German dry brown coal with a water content of 12%, a A- scheschmelzpunkt of 1,250 ⁰ C and a grain size of 0 to 4 mm are used. The amount of dry brown coal used is 45 t / h and is fed to the incinerator at a temperature of 60 ^° C. The entry of the dry lignite takes place with the help of Screws and over 2 to 3 symmetrically distributed inclined tubes in the region of the truncated cone-shaped portion of the second combustion zone (2) at a distance (hl) of 5 m above the center of the combustion agent jet. The supply takes place at an entry angle α ₂ of 130 °.

The radial speed profile of the second combustion zone (2) shows a design typical of homogeneously fluidized fluidized beds. The axial gas velocity increases slightly in the flow direction. With a combustion chamber diameter of 8 m, this is 5.2 m / s.

The conversion of the dry lignite takes place to 90% in the second combustion zone (2) at temperatures between 750 ⁰ C and 950 ⁰ C, which locally in the areas in which oxygen-containing second combustion agent (2) is injected, higher temperatures may occur, so that using the oxygen-containing second combustion means (4) at least locally occurring temperatures exceed the ash melting point of 1250 ⁰ C and it comes to a granulation of about 10% of ash components.

At the lower end of the combustion chamber (1) takes place in an open and free of internals designed first combustion zone (3) the ash discharge (7) and the supply of the required for the complete combustion of the carbon amount of first combustion agent (6), consisting of 15 vol .-% oxygen and 85 vol. 1 .-% steam, in countercurrent at a temperature of 200 ⁰ C.

The first combustion agent (6) is used for the most complete possible combustion of the remaining carbonaceous constituents and for the oxidation of the ashes in a first combustion zone (3), which is designed as a moving bed. Furthermore, the coarse-grained residue is cooled as a bottom product (7), which consists essentially of ash and ash granules, before it leaves the lower end of the first combustion zone (3) of the combustion chamber (1) trouble-free.

The combustion process takes place with λ = 1.1. In this case, 1.205 m ³ (iN) θ ₂ / kg dry lignite are fed. (54,000 m ³ (iN) O ₂ / h at 250 MW (Ih)) The speed with which the solid residues remaining below the moving bed of the first combustion zone (3) moving from top to bottom are discharged by means of a screw conveyor from the lower end of the first combustion zone (3) of the combustion chamber (1) is essentially determined the residence time of the solids and dusts in the combustion chamber (1), which is required at the given conditions, in particular temperatures, to achieve the desired carbon conversion of 100%.

In the upper part of the combustion chamber (1), the dust-laden combustion gas (8) is discharged. The entrained with the combustion gas dust has a carbon content of usually <2 Ma. -% on.

In a separator (10) adjoining the upper region of the combustion space (1), a large part of the dust of the combustion gas, primarily the coarse dust, is separated and fed to the combustion space (1) above the combustion agent injection of the second combustion agent (4) into the second combustion zone (2 ). The supply of the recirculated dust (11), mainly coarse dust, takes place with a distance (h2) of 3 m above the upper end of the first combustion zone (3). The return of the solid takes place in a entry angle 013 of 130 °.

It has also been found that an average carbon content in the solid fraction in the second combustion zone (2), a highly expanded or circulating fluidized bed, of not more than 2.25% for limiting the temperature in the combustion chamber (1) to <1.250 ⁰ C leads and so that no malfunctioning slag formation occurs.

If the combustion of solid fuel (5) were carried out in a process comparable to the invention with air and this air as a second combustion medium in a comparable second combustion zone (2), a highly expanded or circulating fluidized bed, would be used to achieve a temperature in the combustion chamber (1) of 1250 ⁰ C and no malfunctioning slag formation, about 3.5% carbon content in the solids content of the second combustion zone (2) required. The carbon content in the solid fraction in the second combustion zone (2), a highly expanded or circulating fluidized bed, is with the combustion of solid fuel in a combustion chamber (1) as shown in FIG. 1 with oxygen, versus the combustion of solid fuel in an as in Figure 1 illustrated combustion chamber (1) with air, reduced by 1 to 1.5 percentage points.

LIST OF REFERENCE NUMBERS

1. combustion chamber

2. Second combustion zone (strongly expanded or circulating fluidized bed)

3. First combustion zone (moving bed)

4. Second combustion means

5. Solid fuel

6. First combustion agent

7. Ash / bottoms product

8. dust-laden combustion gas

9. combustion gas

10. separator

11. Returned dust

Claims

claims 1. A method for burning solid fuels with free oxygen-containing combustion agents, wherein dust laden gases leave a combustion chamber on the top side and predominantly coarse-grained products the combustion chamber as a bottom product on the underside, wherein the combustion chamber, the necessary for the complete combustion combustion medium are supplied, characterized in that Combustion chamber is separated into at least a first combustion zone, wherein this is designed as a moving bed, and in at least one second combustion zone located above, which is designed as a highly expanded or circulating fluidized bed, that the separation of the combustion chamber through at least one lateral, in the middle of Combustion chamber directed injection of the required for the extensive combustion of solid fuels second combustion means, wherein the second combustion agent has an oxygen content> 50 vol .-% a and injected at a rate of> 10 m / s to 100 m / s such that, at the lower end of the first combustion zone, the first combustion means required for practically complete combustion are injected countercurrently, the oxygen content of the gas mixture being <50%, preferably <21% to <10%, and that the solid fuels are introduced into the combustion chamber so far above the upper end of the first combustion zone that no hot spot zones are formed at the level of the entry and its surroundings, in which ashes predominate or completely melts. 2. The method according to claim 1, characterized in that the first and / or the second combustion means in addition to oxygen carbon dioxide, water vapor, NH3 and / or purge gases to be disposed of. 3. The method according to claim 1 or 2, characterized in that the solid fuels are introduced at a distance of 1 to 10 m, preferably from 2 to 5 m above the upper end of the first combustion zone in the combustion chamber. 4. The method according to any one of claims 1 to 3, characterized in that the coarse dust contained in the combustion gas is separated and recycled to the lower part of the second combustion zone. 5. The method according to any one of claims 1 to 4, characterized in that the injection angle αi of the second combustion means 20 ° to 100 °, preferably 45 ° to 90 °. 6. The method according to any one of claims 1 to 5, characterized in that the supply of solid fuels in an entry angle α ₂ from 90 ° to 180 °, preferably from 100 ° to 160 °. 7. The method according to claim 4, characterized in that the return of the coarse dust in an entry angle Ct ₃ from 90 ° to 180 °, preferably from 100 ° to 160 °. 8. The method according to any one of claims 1 to 7, characterized in that the supply of fuels at different heights and distributed over the circumference of the combustion chamber casing erfo Igt. 9. A device for burning solid fuels with free oxygen-containing combustion agents, consisting essentially of a coolable combustion chamber enclosing pressure-resistant reactor housing with a ash discharge at the foot, a combustion gas outlet at the top of the combustion reactor, characterized in that the combustion chamber of the combustion reactor is separated into at least one first combustion zone, which is designed as a moving bed, and in at least one second combustion zone located above it, which is designed as a strongly expanded or circulating fluidized bed, that the separation of the combustion chamber through at least one side, directed into the middle of the combustion chamber injection means for the extensive combustion the solid fuels required second combustion agent takes place and which is designed so that second combustion agent at a speed of> 10 m / s to 100 m / s injected we that at the lower end of the first combustion zone means for injecting the for the virtually complete combustion required first combustion means with an oxygen content of the gas mixture <50%, preferably <21% to <10%, is arranged, and that a fuel entry is arranged so far above the upper end of the first combustion zone, that in height of the entry and the Environment do not form hot spots - zones where ash melts predominantly or completely. 10. The device according to claim 9, characterized in that the injection means consists of a plurality of circumferentially uniformly arranged in a plane of the combustion reactor nozzles and the injection angle αi of the nozzles for the second combustion means 20 ° to 100 °, preferably 45 ° to 90 °. 11. The device according to claim 9, characterized in that the means for injecting the first combustion agent is designed so that it allows the injection in a plurality of superposed areas and / or at the lower end of the first combustion zone. 12. The device according to one of claims 9 to 11, characterized in that the fuel input is designed as a Schrägrohreintrag and oriented so that the supply of solid fuels in an entry angle α ₂ of 90 ° to 180 °, preferably from 100 ° to 160 ° he follows. 13. The apparatus according to claim 12, characterized in that the fuel input consists of several distributed on the circumference of the combustion reactor in the same or different heights arranged Schrägrohreinträge. 14. Device according to one of claims 9 to 13, characterized in that the combustion gas outlet means for dust removal and dust recycling into the lower part of the second combustion zone is connected downstream and the means for dust recirculation is arranged so that the dust recirculation in an entry angle Ct ₃ from 90 ° to 180 °, preferably from 100 ° to 160 °.