EP0409037A1 - Combustion chamber for the combustion of at least partially combustible materials - Google Patents

Abstract

A combustion chamber for combusting a substance includes a burner and at least three successively disposed parts including a primary chamber, a secondary chamber and an ash discharge chamber. The burner is associated with and conducts a first air flow to the primary chamber. The primary chamber has an inlet for conducting a second air flow for substoichiometric combustion of a substance to be combusted at a temperature below an ash softening point and without clinker flow. The secondary chamber has an inlet for conducting a third air flow for brief, intensive, complete combustion of the substance discharged from the primary chamber with clinker flow, and the secondary chamber has walls and a material lining the walls being resistant to fluid clinker. A process for combusting a substance being at least partially formed of combustible material includes feeding an air flow to the substance for substoichiometrically combusting the substance at a temperature below an ash softening point without clinker flow but with formation of a residue, and subsequently admixing a further air flow with the residue of the substoichiometric combustion for completely combusting the residue and forming flue gas and flowing ash. Prepared pyrolysis residue and incompletely burned gas may be discharged from a pyrolysis reactor as the at least partially combustible material made by low-temperature carbonization of trash in a system for thermal trash disposal.

Description

The invention relates to a combustion chamber for burning a good, which is equipped with a burner, in particular a combustion chamber of a plant for thermal waste disposal with a pyrolysis reactor, which converts waste into carbonization gas and essentially non-volatile pyrolysis residue, with a discharge device for the non-volatile pyrolysis residue on the pyrolysis reactor is connected, which has a carbonization gas outlet for discharging carbonization gas, and wherein the carbonization gas and processed pyrolysis residue are fed to the combustion chamber. The invention also relates to a method for burning at least partially combustible substances.

Previously known uncooled combustion chambers have a fire-resistant coating over their entire inner surface. A lining with refractory refractory bricks is common. Coating with a refractory so-called ramming compound is also common. In such a combustion chamber, when ash-containing fuel is burned, liquid ash is formed during operation, which can attack the surfaces of the stones or the ramming mass. It is therefore necessary to renew or repair the fireclay bricks or ramming paste after a certain period of operation. These operating intervals between two repairs to a combustion chamber can be extended by using special resistant firebricks. Such refractory bricks, which are largely resistant to liquid ash, are very expensive.

A system for thermal waste disposal is known from EP 0 302 310 A1. This system turns waste into one Pyrolysis reactor converted into carbonization gas and essentially non-volatile pyrolysis residue. A discharge device for the non-volatile pyrolysis residue is connected to the pyrolysis reactor and has a carbonization gas outlet connection for discharging carbonization gas. The carbonization gas and processed, for example ground pyrolysis residue, enter a combustion chamber. A combustion takes place there, producing molten slag. In addition, flue gas is generated, which is discharged from the combustion chamber via a flue gas line. The molten slag is also discharged from the combustion chamber. After cooling, it is then in a glazed form.

The combustion chamber of this system, like other known combustion chambers, is lined with firebricks or ramming paste. As with other combustion chambers, there is an expensive lining so that the operating interval between two necessary maintenance of the combustion chamber is as large as possible.

The invention has for its object to provide a combustion chamber that is inexpensive to build and yet only rarely requires maintenance. In particular, the inner lining of the combustion chamber should be inexpensive to manufacture and ensure a long, undisturbed operating time. A method for burning at least partially combustible materials is also to be specified, which requires an inexpensive inner lining of a combustion chamber.

The first object is achieved according to the invention in that the combustion chamber is at least in three parts, a primary chamber, a secondary chamber and an ash discharge chamber being arranged one behind the other in that the burner is assigned to the primary chamber, a first air flow (primary air) into the burner via the burner Primary chamber arrives that the primary chamber has an inlet for a second air stream (secondary air) for the substoichiometric combustion of the material at a temperature un has below the ash softening point and without slag flow, and that the secondary chamber has an inlet for a third air stream (tertiary air) for short-term, intensive, complete combustion of the discharge from the primary chamber with slag flow, the walls of the secondary chamber being coated with a material which is resistant to liquid slag are.

The ash discharge space has, for example, a floor in which there is an ash outlet hole. In addition, the ash discharge space has, for example, a flue gas discharge opening.

The primary chamber is designed for substoichiometric combustion. That the combustion always remains substoichiometric, there must always be an air deficit in the primary chamber. Inlets for two separate air flows, the primary air and the secondary air, in the primary chamber can always provide the required air flow at any point in the primary chamber without too much air being present in part of the primary chamber, for example in the upper region. Due to the substoichiometric combustion, the temperature in the primary chamber does not exceed the ash softening point. The ash softening point of a certain ash is a temperature at which, by definition, a certain deformation and stickiness develop. Since the ash softening point in the primary chamber is not exceeded, no liquid ash or slag can get to the inner lining of the primary chamber. As a result, it is not necessary to line the primary chamber with expensive refractory refractory bricks that resist liquid ash or slag, or with a suitable ramming compound.

According to the invention, the secondary chamber adjoining the primary chamber has an inlet for tertiary air. This tertiary air creates an air overflow in the secondary chamber Shot set, which ensures short-term, intensive and complete combustion. The temperature exceeds the ash flow point, and there is a slag flow on the inner surface of the secondary chamber. The ash flow point of a particular ash is a temperature at which the toughness is so low that the ash flows. According to the invention, the secondary chamber is therefore coated with a heat-resistant material that is resistant to liquid slag. This material is more expensive than the material used to coat the primary chamber. The system according to the invention, however, only requires the expensive material to coat a part of the combustion chamber, namely the secondary chamber. You can get by with less expensive material.

The ash discharge chamber is connected to the secondary chamber. There is an ash outlet hole in the bottom. Only the floor of the ash discharge area that comes into contact with liquid ash or slag is coated with material that is resistant to liquid slag. The ash discharge chamber has a flue gas discharge opening, to which a flue gas duct leading to a chimney can be connected.

When the combustion chamber according to the invention is used in a plant for thermal waste disposal, a so-called smoldering plant, pyrolysis residue processed in the combustion chamber is burned together with smoldering gas. This leaves flue gas and liquid ash or slag, which can be further processed to melt granulate in a water bath.

With the combustion chamber according to the invention the advantage is achieved that a large part of the combustion chamber, the primary chamber, manages without an expensive lining. Only a small part of the combustion chamber, the secondary chamber requires a lining that is resistant to liquid slag. The combustion chamber according to the invention can be carried out inexpensively and ensures a long, undisturbed operating time.

For example, the walls of the secondary chamber are cooled. As a result, an expensive coating of the interior of the secondary chamber to protect against liquid ash and slag can also be dispensed with. With an inexpensive coating, a long, undisturbed operating time is guaranteed.

A coating can be chosen which is less expensive than a coating which would be necessary in an uncooled chamber in which liquid ash or slag flows.

The inlet for the second air stream (secondary air) is, for example, in the burner. In another example, the secondary air inlet is located at the top of the primary chamber, to the side of the burner port. Another example provides that several inlets for secondary air are arranged on the primary chamber over its entire length. In particular, this has the advantage that the air concentration must be set everywhere in the entire primary chamber, which ensures substoichiometric combustion at a temperature below the ash softening point. The air supply to the primary chamber should be selected so that on the one hand the temperature of the ash softening point is not exceeded and on the other hand the substoichiometric combustion in the entire primary chamber must always be maintained. This is ensured by the fact that in addition to the primary air, secondary air, particularly at the specially selected points, can get into the primary chamber. The air flow can be optimally adjusted at every point in the primary chamber.

For example, one or more inlets for the secondary air in the primary chamber are oriented obliquely, that is to say with a tangential component, to the wall of the primary chamber. This creates a vortex in the medium in the primary chamber, which continues from the primary chamber into the secondary chamber.

This supply of secondary air mixes the medium in the primary chamber. The weak swirl that arises at the entrance of the secondary chamber favors the formation of a swirl in the secondary chamber.

For example, inlets for the secondary air in the primary chamber are arranged one below the other in parallel planes. Correspondingly, two or more inlets for the tertiary air can also be arranged in the secondary chamber in parallel planes. By supplying air at several levels, the combustion in the primary chamber can also be controlled in the secondary chamber.

The inlets for air can open into indentations which are arranged in the inner wall of the primary chamber and / or the secondary chamber. This protects the outlets from the material in the combustion chamber.

A roof-shaped projection, which is arranged, for example, above an inlet on the inner wall of the combustion chamber, can also serve to protect an opening.

For example, the primary chamber is divided into partial combustion chambers connected in series. Inlets for the second air flow are, for example, in each partial combustion chamber, in its upper section, that is, in the flow direction at the entrance of the partial combustion chamber. With the subdivision of the primary chamber into partial combustion chambers and with the air supply in each of these partial combustion chambers, an optimal air supply into the primary chamber and an optimal mixing of the medium in the primary chamber is achieved.

For example, the inlet for tertiary air into the secondary chamber is inclined, that is, aligned with a tangential component to the wall of the secondary chamber. This will directly in the Secondary chamber creates a twist that pushes the heavy parts of the medium in the secondary chamber towards the wall. There, liquid ash is deposited on the wall and flows along the wall to the outlet opening of the secondary chamber. From there, the liquid ash arrives in the ash discharge area. The effect of the swirl generated in the secondary chamber is significantly improved if a swirl has already been generated in the primary chamber. By creating a swirl in the medium that is located in the combustion chamber, the advantage is achieved that liquid ash and slag can be separated from the flue gas and also from other substances quickly and reliably.

Like the primary chamber, the secondary chamber can also be divided into partial combustion chambers connected in series. Correspondingly there are inlets for the third air flow, for example in each partial combustion chamber of the secondary chamber in its upper section, that is to say in the flow direction at the entrance of the partial combustion chamber. With the subdivision of the secondary chamber into partial combustion chambers and with the air supply to each of these partial combustion chambers, precise control of the combustion in the secondary chamber is possible. Improved mixing of the medium in the secondary chamber is also achieved.

The walls of the secondary chamber are covered with stones, for example, from the inside. These stones are made of a material that is resistant and is not attacked by slag and ash. According to a further example, the walls of the secondary chamber are coated on the inside with a ramming compound which has the appropriate properties. Since only the secondary chamber is to be equipped with high-quality stones or ramming masses, this results in a cost advantage compared to a combustion chamber, which must be lined entirely with high-quality stones or ramming masses.

In order to make the walls of the secondary chamber even cheaper, these walls are cooled. To do this, the walls contain the secondary Chamber, for example, cooling channels that hold a coolant, especially water or air. This constant cooling of the secondary chamber walls from the outside prevents excessive overheating of the inner surfaces of the walls wetted with the liquid ash or slag. As a result, inexpensive liners can be used even in the secondary chamber, as in the primary chamber. As a result of the cooling, a thin, firm layer of slag forms on the surface of the lining, on which a liquid slag film forms on the inside. The solid slag layer protects the lining material underneath from being attacked by the liquid slag. So you do not need an expensive material resistant to slag flow for the lining of the secondary chamber.

Airborne dust, for example, can be fed to the primary chamber or the secondary chamber or the ash discharge chamber. The supply can take place via special supply openings, but also through the burner or together with secondary air or tertiary air. If the fly dust can be easily incorporated into a slag bath due to its properties, then it is particularly advantageous to feed the fly dust directly to the ash discharge area. In this way, the dust is bound into the slag.

The ash discharge space is, for example, wider than the exit of the secondary chamber. As a result, the slag or liquid ash carried out of the secondary chamber does not reach the side walls of the ash discharge space. Therefore, only the floor of the ash discharge area must be covered with material that is resistant to liquid slag. This can be expensive stones or ramming masses, or also inexpensive stones or ramming masses, if a cooling device is available in the floor of the ash discharge chamber. The cooling device can be constructed such that the bottom of the ash discharge space cooling channels contains, for receiving a coolant, especially water or air.

The floor of the ash discharge area runs e.g. horizontal, which, when cooled, can form a layer of slag around the ash outlet hole, protecting the soil from erosion.

The exit of the secondary chamber is surrounded, for example, in the secondary chamber by a ring which has a drainage point on a side facing away from the flue gas discharge opening. For this purpose, measured from a fictitious horizontal plane, the height of this ring at a point facing away from the flue gas discharge nozzle of the ash discharge space is smaller than usual. This results in a groove that runs around the exit of the secondary chamber. When the combustion chamber is operating, this channel fills with liquid ash or slag. Where the ring is the lowest compared to a horizontal plane, the slag and the channel are filled in a jet from the secondary chamber into the ash discharge area. Since the lowest point of the ring is located at a point facing away from the flue gas discharge nozzle of the ash discharge area, the entire liquid slag flows into the ash discharge area with only one jet. The ring therefore has the advantage that there is only one ash jet from the secondary chamber into the ash discharge space, which is not crossed by the flue gas flowing out. The ash flow is therefore not disturbed by the flue gas flow. If both liquid ash and flue gas flow out of the wide exit of the secondary chamber in an uncontrolled manner, flue gas and slag could be mixed in the ash discharge chamber. Instead of getting to the ash outlet hole, small pieces of slag would be carried away with the flue gas. This is prevented by the ring in the secondary chamber.

An ash trap, for example, is arranged in the flue gas discharge nozzle of the ash discharge space. This has the advantage that fewer ash particles get into the flue gas duct. Such particles would contaminate existing heat exchanger heating surfaces in the flue gas line.

For example, a heating burner is arranged in the ash discharge area. It is used if the liquid slag or ash coming from the secondary chamber should have poor flow properties. Then the slag in the ash discharge area is heated again so that it reaches the ash outlet hole and exits there. If the slag or ash is sufficiently fluid, the heating burner remains switched off. The heating burner is fed with an external fuel. However, it can also be fed with carbonization gas that originates from a pyrolysis reactor. This saves external fuel.

The combustion chamber according to the invention has the particular advantage that long operating intervals can be carried out without maintenance or repair work on the combustion chamber if the combustion chamber is inexpensive.

The second task, to provide a method for burning a good from at least partially combustible substances, is achieved according to the invention in that the good, which is for example a mixture of processed pyrolysis residue and carbonization gas, is supplied with an air stream (primary air and secondary air) and the mixture is sub-stoichiometrically burned at a temperature below the ash softening point without the slag flow, then another air stream (tertiary air) is mixed into the residue of the sub-stoichiometric combustion and the residue is then burned completely, whereby flue gas and flowing ash are formed.

For the implementation of this method, it is advantageous to have a cost-effective and at the same time resistant combustion chamber that requires little maintenance. The combustion chamber described above is particularly suitable.

For example, a swirl is generated in the material to be treated, but especially in the residue of the sub-stoichiometric combustion, whereby the liquid ash that is formed is carried outside and against a container wall, e.g. the combustion chamber wall. This improves the separation of flue gas and liquid ash.

For example, the dust to be treated or the residue of the substoichiometric combustion is mixed in, which can originate from the method according to the invention and which is therefore returned. Flying dust can also be mixed with the still flowing ash or slag. The fly dust is thus advantageously wholly or partly incorporated into later solid slag granules.

For example, after the liquid ash has been formed, it is heated again to prevent premature solidification. The slag then flows better out of the ash discharge chamber of the combustion chamber.

Finally, the resulting flue gas can be cooled in a heat exchanger in the burner or in separate feed points e.g. are fed into the combustion chamber together with the combustion air. This means that the temperature required for the process can be set at any point in the combustion chamber.

With the system and with the method according to the invention, the advantage is achieved that the material to be treated, which is in particular pyrolysis residue and carbonization gas from a carbonization process, is reliable in an inexpensive combustion chamber that requires little maintenance and repair to be broken down into liquid ash and flue gas.

• FIG 1 zeigt eine Brennkammer mit in Teilbrennkammern unter­teilter Primärkammer.
• FIG 2 zeigt schematisch eine Wand einer Sekundärkammer, die in Teilbrennkammern unterteilt ist.
• FIG 3 zeigt schematisch eine Wand einer Brennkammer mit Ein­buchtungen zur Aufnahme von Luftzuführungen.
• FIG 4 zeigt schematisch eine Wand einer Brennkammer mit Luft­zuführungen und darüber angeordneten dachförmigen Vor­sprüngen.

An embodiment of the system according to the invention, in which the method according to the invention can run, is explained in more detail with reference to the drawing:

• 1 shows a combustion chamber with a primary chamber divided into partial combustion chambers.
• 2 shows schematically a wall of a secondary chamber which is divided into partial combustion chambers.
• 3 schematically shows a wall of a combustion chamber with indentations for receiving air supplies.
• 4 schematically shows a wall of a combustion chamber with air feeds and roof-shaped projections arranged above it.

A combustion chamber 1 according to FIG. 1, which is equipped with a burner 2, is constructed in three parts. A primary chamber 3, a secondary chamber 4 and an ash discharge chamber 5 are arranged one behind the other. The burner 2 is assigned to the primary chamber 3. The primary chamber 3 consists of three partial combustion chambers 3a, 3b and 3c arranged one behind the other. The primary chamber 3 can also be in one piece. Via the burner 2, an at least partially combustible material, which can be pyrolysis residues PR and smoldering gas SG from a smoldering plant, reaches the primary chamber 3. A first air stream EL, called primary air, also reaches the primary chamber 3 via the burner 2 Primary chamber 3 has inlets 6a, 6b, 6c and 6d distributed over its length for a second air flow ZL called secondary air. Each partial combustion chamber 3a, 3b and 3c is assigned at least one inlet 6a, 6b and 6c. At least one further inlet 6d can be located in the burner 2. A tangential arrangement of at least some of the inlets 6a to d generates vortices in the medium flowing in the primary chamber 3, one of which result in thorough mixing of the medium. A weak swirl is also generated in the primary chamber 3 and propagates into the secondary chamber 4. The air supply to the primary chamber 3 is dimensioned such that there is only substoichiometric combustion. The temperature remains below the ash softening point, so that liquid ash A or slag does not arise. A simple lining 7 of the primary chamber 3, for example with inexpensive stones, is therefore sufficient. The primary chamber 3 is connected directly to the secondary chamber 4 via an outlet 8, which can be designed without or with retraction. In the area of the secondary chamber 4 facing the primary chamber 3, at least one inlet 9 for a third air flow DL called tertiary air is arranged. This air flow DL is dimensioned such that the secondary chamber 4 is completely combusted with the residue R fed from the primary chamber 3. This combustion takes place at a temperature above the ash softening point, so that liquid ash A or slag is formed. The inlets 9 for the third air flow DL, like the inlets 6a to d, are also obliquely aligned with the wall of the combustion chamber 1 for the second airflow ZL, that is to say with a tangential component. This creates a swirl in the residue R, which is located in the secondary chamber 4, through which liquid ash A or slag is deposited on the inner surface of the secondary chamber 4. The liquid ash A flows down there. In order to prevent damage, the inner walls of the secondary chamber 4 are provided with a layer 10 of stones or ramming paste. So that less expensive material is sufficient for the layer 10 of the secondary chamber 4, there are cooling channels 11 in the walls of the secondary chamber 4 through which a coolant, in particular water or air, flows. Due to the constant cooling, the walls of the secondary chamber 4 are not at all or only slightly attacked by the liquid ash A, since a solid layer of slag forms between the liquid ash layer and the cooled wall due to the cooling. The ash discharge chamber 5 is connected to the secondary chamber 4 via a narrow outlet 12. Into this ash discharge area 5 the liquid ash A or slag passes through an annular groove 13 which surrounds the outlet 12 and is separated from it by an annular bead 14. The bead 14 has a minimal height at a certain point compared to a fictitious horizontal plane. A drain point 14a is thereby formed. Liquid ash A, which flows down the walls of the secondary chamber 4, first collects in the groove 13 and then passes over the bead 14 at its lowest point, namely at the drain point 14a. By collecting the liquid ash A before it is discharged into the ash discharge space 5, a uniform, continuous ash jet is provided. Because the outlet 12 is narrow, flue gas RG reaches the ash discharge chamber 5 at high speed. The initially directed downward flue gas stream is deflected on a floor 15 of the ash discharge chamber 5. The floor 15 acts like a baffle. Ash particles are separated from the flue gas RG.

The ash discharge space 5 has a flue gas discharge opening 16 through which the flue gas RG is discharged. If necessary, there is an ash trap 17 in front of the flue gas discharge opening 16, which retains further ash particles. To remove the liquid ash A or slag, there is an ash outlet hole 18 in the ash discharge space 5. This ash outlet hole 18 is swept by hot flue gas RG and is thus heated so that ash A or slag cannot solidify in the ash outlet hole 18. The ash outlet hole 18 can therefore not clog.

The ash discharge space 5 is wider than the outlet 12 of the secondary chamber 4. Therefore, liquid ash A or slag cannot reach the side walls of the ash discharge space 5, which therefore need not be made of a highly resistant material. The bottom 15 of the ash discharge space 5 is provided with a layer 19 of ramming mass or stones, similar to the walls of the secondary chamber 4, and often contains cooling channels 20.

Cooling ducts can also be present in the side walls. Due to the cooling, a solid slag layer forms on the floor 15 of the ash discharge space 5 during the operation of the combustion chamber 1, which protects the floor 15 from erosion. On this solid slag layer, which serves as a heat insulation layer, the liquid ash A flows to the ash outlet hole 18 and from there reaches a water container 21, where it granulates. The lowest point of the annular bead 14 around the outlet 12, the outlet point 14a of the secondary chamber 4 is at a position which is the greatest distance from the flue gas discharge opening 16. This ensures that 5 liquid ash A and flue gas RG do not cross in the ash discharge space 5, which would lead to swirling of the flue gas RG and entrainment of liquid ash in the flue gases. In order to keep the liquid ash A in the ash discharge chamber 5, if necessary, there is a heating burner 22 in the ash discharge chamber 5, which can be fed with an external fuel B or with a smoldering gas SG from a smoldering furnace. Airborne dust FS, which was previously filtered out of the flue gas RG, and flue gas RG can also be fed back into the combustion chamber 1.

The combustion chamber in FIG. 2 differs from the combustion chamber 1 in FIG. 1 only in that, in addition to the primary chamber 3, the secondary chamber 4 is also divided into partial combustion chambers 4a, 4b, 4c. Each partial combustion chamber 4a, 4b and 4c is assigned at least one inlet 9a, 9b and 9c. This results in a good mixing of the medium in the secondary chamber 4. The weak swirl already generated in the primary chamber 3 is also supported in the secondary chamber 4. In addition, the air supply and thus the combustion can be controlled well.

The air inlets 6b, 6c in the primary chamber 3 can, for example, be designed such that the inner wall of the primary chamber 3, as shown in FIG. 3, has indentations 23, the Inlets 6b, 6c open into these indentations 23. The inlets 6b, 6c are in a protected position. Corresponding indentations for receiving the inlets 9b, 9c can also have the inner wall of the secondary chamber 4.

According to FIG. 4, a roof-shaped projection 24 can be arranged on the inner wall of the primary chamber 3 above an inlet 6b, 6c for the protection thereof. A corresponding roof-shaped projection can also be arranged above an inlet 9b, 9c on the inner wall of the secondary chamber 4.

In the combustion chamber 1, fuels, in particular pyrolysis residues PR and smoldering gas SG, which originate from a smoldering drum, can be completely burned and converted into flue gas RG and liquid ash A or slag, without the need for complex and expensive coatings on the combustion chamber 1 and without frequent maintenance and repairs to the combustion chamber 1 are necessary.

Claims (33)

1. combustion chamber (1) for burning a good, which is equipped with a burner (2),
in particular combustion chamber (1) of a plant for thermal waste disposal with a pyrolysis reactor which converts the waste into carbonization gas (SG) and essentially non-volatile pyrolysis residue (PR), a discharge device for the non-volatile pyrolysis residue (PR) being connected to the pyrolysis reactor and connecting a carbonization gas outlet nozzle for discharging carbonization gas (SG), and wherein the carbonization gas (SG) and processed pyrolysis residue (PR) are fed to the combustion chamber (1),
characterized,
that the combustion chamber (1) is at least in three parts, a primary chamber (3), a secondary chamber (4) and an ash discharge chamber (5) being arranged one behind the other,
that the burner (2) is assigned to the primary chamber (3), a first air stream (primary air) (EL) entering the primary chamber (3) via the burner (2),
that the primary chamber (3) has an inlet (6a, 6b, 6c, 6d) for a second air stream (secondary air) (ZL) for the substoichiometric combustion of the material at a temperature below the ash softening point and without slag flow, and
that the secondary chamber (4) has an inlet (9) for a third air stream (tertiary air) (DL) for short-term, intensive, complete combustion of the discharge from the primary chamber (3) with slag flow, the walls of the secondary chamber (4) having a material resistant to liquid slag are coated. 2. combustion chamber according to claim 1,
characterized in that the ash discharge space (5) has a bottom (15) in which there is an ash outlet hole (18). 3. combustion chamber according to one of claims 1 or 2,
characterized in that the ash discharge space (5) has a flue gas discharge opening (16). 4. combustion chamber according to one of claims 1 to 3,
characterized,
that the walls of the secondary chamber (4) are cooled. 5. combustion chamber (1) according to one of claims 1 to 4,
characterized,
that the inlet (6d) for the second air flow (secondary air) (ZL) is in the burner (2). 6. combustion chamber (1) according to one of claims 1 to 5,
characterized,
that the inlet (6a) for the second air flow (secondary air) (ZL) is located on the upper section of the primary chamber (3) to the side of the burner (2). 7. combustion chamber (1) according to one of claims 1 to 6,
characterized,
that several inlets (6a - 6d) for the second air stream (secondary air) (ZL) are distributed in the primary chamber (3) over its height. 8. combustion chamber (1) according to one of claims 1 to 7,
characterized,
that an inlet (6a) or several inlets (6a - 6d) for the second air flow (ZL) in the primary chamber (3) is / are arranged obliquely to the wall of the primary chamber (3). 9. combustion chamber (1) according to one of claims 1 to 8,
characterized,
that several inlets (6a - 6d) for the second air flow (ZL) in the primary chamber (3) and / or several inlets (9, 9a - 9c) for the third air flow (DL) in the secondary chamber (4) in parallel planes with each other are arranged. 10. combustion chamber (1) according to one of claims 1 to 9,
characterized,
that an inlet (6b, 6c, 6, 9) opens into an indentation (23) arranged in the wall of the primary chamber (3) and / or the secondary chamber (4). 11. combustion chamber (1) according to one of claims 1 to 10,
characterized,
that a roof-shaped projection (24) is arranged above the inlet (6b, 6c, 6, 9) inside the chamber (3, 4). 12. combustion chamber (1) according to one of claims 1 to 11,
characterized in that the primary chamber (3) is divided into partial combustion chambers (3a, 3b, 3c) connected in series. 13. combustion chamber (1) according to claim 12,
characterized,
that the inlets (6a - 6c) for the second air flow (secondary air) (ZL) are in the upper section of each partial combustion chamber (3a, 3b, 3c). 14. combustion chamber (1) according to one of claims 1 to 13,
characterized,
that an inlet (9) or several inlets (9a - 9c) for the third air flow (DL) (tertiary air) in the secondary chamber (4) is / are arranged obliquely to the wall of the secondary chamber (4). 15. combustion chamber (1) according to one of claims 1 to 14,
characterized,
that the secondary chamber (4) is divided into partial combustion chambers (4a, 4b, 4c) connected in series. 16. combustion chamber (1) according to claim 15,
characterized,
that the inlets (9a - 9c) for the third air flow (tertiary air) (DL) are in the upper section of each partial combustion chamber (4a, 4b, 4c). 17. combustion chamber (1) according to one of claims 1 to 16,
characterized,
that the inner walls of the secondary chamber (4) are covered with stones. 18. combustion chamber (1) according to one of claims 1 to 17,
characterized,
that the walls of the secondary chamber (4) are provided on the inside with a layer (10) of ramming compound. 19. Combustion chamber (1) according to one of claims 1 to 18,
characterized,
that the walls of the secondary chamber (4) contain cooling channels (11) for receiving a coolant, in particular water or air. 20. Combustion chamber (1) according to one of claims 1 to 19,
characterized,
that the primary chamber (3) or the secondary chamber (4) or the ash discharge chamber (5) can fly dust (FS) can be supplied. 21. combustion chamber (1) according to one of claims 1 to 20,
characterized,
that the ash discharge space (5) is wider than the outlet (12) of the secondary chamber (4), and that only the bottom (15) and not the side walls of the ash discharge space (5) are coated and / or cooled. 22. combustion chamber (1) according to one of claims 1 to 21,
characterized,
that the bottom (15) of the ash discharge space (5) is provided with a layer (19) of stones or ramming paste. 23. combustion chamber (1) according to one of claims 1 to 22,
characterized,
that the bottom (15) of the ash discharge space (5) contains cooling channels (20) for receiving a coolant, in particular water or air. 24. Combustion chamber (1) according to one of claims 1 to 23,
characterized,
that the ash discharge chamber (5) has a horizontally extending floor (15). 25. combustion chamber (1) according to one of claims 2 to 24,
characterized,
that the outlet (12) of the secondary chamber (4) in the secondary chamber (4) is surrounded by an annular bead (14) which has a drainage point (14a) on a side facing away from the flue gas discharge opening (16). 26. Combustion chamber (1) according to one of claims 2 to 25,
characterized,
that an ash trap (17) is arranged in the flue gas discharge nozzle (16) of the ash discharge space (5). 27. combustion chamber (1) according to one of claims 1 to 26,
characterized,
that a heating burner (22) is arranged in the ash discharge chamber (5). 28. combustion chamber (1) according to claim 27,
characterized,
that the heating burner (22) is fed with carbonization gas (SG). 29. Process for burning a good (PR, SG, FS) from at least partially combustible materials, in particular processed pyrolysis residues (PR) and carbonization gas (SG), which are formed by smoldering waste,
characterized,
that the material (PR, SG, FS) is supplied with an air flow (primary air and secondary air) (EL and ZL) so that it is burned substoichiometrically at a temperature below the ash softening point without slag flow, so that another air flow (tertiary air) (DL ) is mixed with the residue (R) of the substoichiometric combustion, so that the residue (R) is completely burned, whereby flue gas (RG) and flowing ash (A) are formed. 30. The method according to claim 29,
characterized,
that a vortex is generated in the good (PR, SG, FS) and / or in the residue (R). 31. The method according to any one of claims 29 or 30,
characterized,
that the good or the residue (R) or the flowing ash (A) is mixed with dust (FS). 32. The method according to any one of claims 29 to 31,
characterized,
that the ash (A) is heated after its formation. 33. The method according to any one of claims 29 to 32,
characterized,
that the flue gas (RG) is fed back into the material and / or into the residue (R) of the substoichiometric combustion.

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