EP0202443A2 - Method and device for the combustion of liquid and/or solid pulverulent fuels - Google Patents

Abstract

A method of and apparatus for burning liquid fuels such as oil or the like and/or solid fuels, especially coal, peat or the like, in pulverized form, the latter either in dry condition or mixed with a carrier liquid such as water and/or oil to form an emulsion being introduced together with the liquid fuel into a combustion chamber while creating a recirculating flow profile, said flow profile being confined by a rotating outer flow of air. For thorough breaking-up of the fuel introduced into the combustion chamber the fuel inlet is constituted by a plurality of inlet ports approximately evenly distributed along a circumference, especially a circle, the liquid-fuel inlet ports and the inlet ports for solid fuel or a fuel emulsion being alternately arranged along said circumference. The fuel inlet ports may be directed either radially and/or at an outward inclination in the direction of flow, based on the longitudinal axis of the combustion chamber. Preferably, a central compressed-air injection is also provided.

Description

The invention relates to a method and a device for burning liquid and / or solid fuels according to the preamble of patent claim 1 and patent claim 14.

Over the years, various variants for burning both liquid fuels, such as oil or the like, and solid fuels, in particular coal, peat or the like, in powdered form have been proposed, the latter mostly mixed with a carrier liquid, such as water and / or oil, as an emulsion be introduced into a combustion chamber. The introduction of the fuels into the combustion chamber usually takes place with the formation of a recirculating flow profile, this being limited by a rotating external air flow. Combustion of a suspension of powdered coal in liquid has been found to be relatively difficult in practice; Above all, the aim was to prevent the fuel inlet openings or burner nozzles opening into the combustion chamber from becoming blocked. The combustion efficiency was also limited. To overcome these problems, a burner is proposed in DD-PS 145 316, which is a combination of a so-called rotary burner with a toroidal burner. However, tests have shown that this burner can only achieve relatively low efficiencies, especially in the critical starting phase. The reason is presumably that the atomization of the fuels is inadequate, so that inflammation problems occur especially in the starting phase. The enrichment or mixing of the fuels with air is also deficient, which also affects the efficiency.

Based on this prior art, the present invention has for its object to provide a method and an apparatus for burning liquid and / or solid fuels in pulverized form, in which or with which practically complete combustion is possible at a minimal distance in the combustion chamber , the combustion can be maintained with high efficiency even when solid fuels are supplied in a dry form.

This object is achieved in terms of the method by the characterizing measures of claim 1 and in terms of the device by the characterizing measures of claim 14.

By means of the invention, the fuels are introduced into the combustion chamber in finely divided form. Solid and liquid fuels are mixed with one another immediately after they are introduced into the combustion chamber, which means that combustion can be started easily, especially in the start-up phase. The fuels are fed through one (small burner) or several nozzles finely distributed in the form of spray cones into the combustion chamber, whereby the alternating arrangement of nozzles or inlet openings for solid and liquid fuels ensures good mixing and therefore easy ignition. In particular, the fuels introduced are "broken up" into the smallest fuel particles or droplets. In this way, a maximum fuel surface is obtained, whereby the practically complete combustion is achieved at an extremely short distance. The combustion chamber can be built accordingly short.

After the start, it is possible to reduce or even shut off the oil supply and only burn the coal or the like introduced into the combustion chamber dry or mixed with water, oil etc. In this case, it is expedient if the outer air flow has a temperature of approximately 100 ° C. If the temperature of the outer air flow is lower than 100 ° C, it is expedient to additionally introduce oil again in order to maintain a high combustion efficiency.

It is also possible to shut off the coal - or the like - supply and only burn oil, in particular heavy oils. The device (burner) designed according to the invention is therefore suitable both for the combustion of solid fuels and of liquid fuels, specifically separately from one another or in a predetermined mixing ratio.

Preferred process engineering and device engineering measures are described in more detail in claims 2 to 13 and 15 to 34. The central injection of compressed air into the combustion chamber is of particular importance, as a result of which deposits on the end face of the burner nozzle facing the combustion chamber are reliably avoided due to the central recirculation of the hot combustion gases and the unburned fuel particles carried by them. Likewise, the measure according to claims 5 and 15, i.e. by the radial compressed air injection prevents coal or oil particles entering the combustion chamber from being deposited on the end face of the nozzle body facing the combustion chamber due to the negative pressure prevailing in the center directly behind the burner nozzle or the nozzle body.

Surprisingly, the measures according to the invention are reliably avoided with the nozzle body or fuel inlet arranged in the front wall of the combustion chamber, deposits on the side wall opposite the fuel inlet and delimiting the air flow closest to the fuel inlet.

The structural measures according to claims 20 and 21 are of particular importance for optimal combustion. These features literally break up and fan out the pulverized fuel introduced into the combustion chamber. You get a high fine Distribution of the fuels and therefore rapid ignition, especially when mixed with liquid fuel such as oil or the like.

Also of importance are the measures according to claims 23 to 34, which relate to the external air flow and through which the combustion can be influenced significantly, in particular also the flow profile behind the fuel inlet. These measures support a spontaneous fanning out of the fuels introduced into the combustion chamber. Above all, a hollow cone-like flow profile is achieved, which takes on an approximately bell-shaped or apple-shaped shape. The shape of the flow profile is determined by the equilibrium of the centrifugal forces acting on the fuels and central "negative pressure" forces.

If water is used as the carrier liquid for the solid, pulverized fuels, the central recirculation of part of the hot combustion gases also has the great advantage that part of the dissociated water and thus released oxygen flow back centrally to the fuel inlet, which additionally causes the combustion from the inside of the hollow fuel Spray cone is initiated here.

At the start of combustion, only pure oil is preferably injected in order to then increasingly introduce pulverized solid fuels. As explained, the oil supply can then be switched off completely at a sufficiently high temperature of the external air flow and also of the compressed air blown in centrally and optionally the compressed air mixed with the solid fuel. The procedure is reversed when switching off the combustion. The powdered fuel is increasingly removed until finally only oil remains as fuel.

This reliably prevents clumping or clogging of the inlet openings for solid fuels when switching off.

As has also been explained above, the solution according to the invention is also extremely suitable for the combustion of oil, in particular heavy oil. On the basis of the measures according to the invention, the highest fine distribution or atomization of the oil introduced into the combustion chamber and thus an extremely large free combustion area are obtained, with the result that almost complete combustion is obtained at the shortest distance.

Solid fuels are primarily coal, e.g. Hard coal, bituminous coal, gas-rich coal or a mixture thereof.

• Fig. 1 einen Teile einer ersten Ausführungsform der erfindungsgemäßen Vorrichtung (Brennerteil) im schematischen Längsschnitt,
• Fig. 2 den Düsenkörper der Vorrichtung nach Figur 1 im Längsschnitt,
• Fig. 3 den Düsenkörper nach Figur 2 in Vorderansicht,
• Fig. 4 den Einlaß für feste Brennstoffe bzw. Brennstoffemulsion im Schnitt und vergrößertem Maßstab,
• Fig. 5 einen Teil einer zweiten Ausführungsform der erfindungsgemäßen Vorrichtung (Brennerteil) im schematischen Längsschnitt,
• Fig. 6 den Düsenkörper der Vorrichtung nach Figur 5 im Längsschnitt, und
• Fig. 7 den Düsenkörper nach Figur 6 im Querschnitt längs Linie VII-VII.

The invention is described in more detail below with reference to two exemplary embodiments of a device for carrying out the method according to the invention. Show it:

• 1 shows a part of a first embodiment of the device according to the invention (burner part) in a schematic longitudinal section,
• 2 shows the nozzle body of the device according to FIG. 1 in longitudinal section,
• 3 shows the nozzle body according to FIG. 2 in a front view,
• 4 the inlet for solid fuels or fuel emulsion in section and on an enlarged scale,
• 5 shows part of a second embodiment of the device according to the invention (burner part) in a schematic longitudinal section,
• Fig. 6 shows the nozzle body of the device of Figure 5 in longitudinal section, and
• Fig. 7 shows the nozzle body of Figure 6 in cross section along line VII-VII.

The oil and / or coal burner shown in a schematic longitudinal section in FIG. 1 has a nozzle body 32 with fuel inlet openings 10, 12 'opening into the combustion chamber 16, which is arranged sunk in the end wall 33 of the combustion chamber and of several gas channels 35, 37 , 39, 41 and 43 is concentrically surrounded. The gas channel 35 immediately surrounding the nozzle body 32 opens into the combustion chamber 16 through an inlet opening 36 which is closest to the fuel inlet. A so-called "primary primary air" flows through the channel 35, which can be enriched with combustion gases of higher temperature, the gas emerging from the opening 36 having a flow rate of 100 to 200 m / s, preferably about 130 m / s. The side walls 60 and 62 delimiting the opening 36 are each conical in shape with the formation of an annular nozzle. Immediately before the "primary primary gas" emerges, it is deflected by swirl elements 46 in the form of guide vanes by approximately 70 ° and thus set in rotation about the longitudinal axis 14 of the nozzle body or combustion chamber. The primary primary gas is blown into the gas channel 35 at a pressure of about 1000 to 1200 mm water column.

The gas channel 35 is surrounded concentrically by a further gas channel 37, the annular inlet opening 38 opening into the combustion chamber 16 likewise is bounded by conical side walls 64 and 66. However, the side walls 64, 66 are directed such that they impart a conical flow profile to the gas flow emerging from the ring opening 38, which constricts the opposite flow profile of the fuels and the "primary primary air" emerging from the ring opening 36. As a result of this, and because the fuel inlet and the ring opening 36 for the primary primary air are set back relative to the ring opening 38 for the so-called "secondary primary air", the gas or air flow emerging from this ring opening causes the flow profile of the fuel, which is already in rotation, to be broken up Fuel mixture reached, ie an additional enlargement of the free surface of the

Fuel shortly after exiting the nozzle body or shortly after entering the combustion chamber 16.

Before the so-called “secondary primary air” flowing through the gas channel 37 emerges, it is also deflected by swirl elements 48 arranged in the area of the ring opening 38 in the form of guide vanes, namely by about 40 to 45 ° to the longitudinal axis 14, that is to say in rotation about the longitudinal axis 14 . The exit velocity of the "secondary primary air" is approximately 120 to 180 m / s, preferably 140 m / s. The annular gap width of the opening 38, like the annular gap width of the opening 36, can be changed by changing the relative position of the side walls 64, 66 delimiting it. The exit velocity of the "secondary primary air" is of course variable in a corresponding manner. The "secondary primary air" is also blown into the annular channel 37 at a pressure of approximately 1000 to 1200 mm of water. The distraction of the "Secondary primary air" through the swirl elements 48 takes place in the same direction as the deflection of the "primary primary air" through the swirl elements 46 arranged in the region of the opening 36.

The "secondary primary air" is preferably not enriched with hot combustion gases, since it serves less as a carrier medium for the fuel introduced into the combustion chamber 16, but rather to enlarge the free surface thereof and to enrich or supply the fuel particles or droplets with oxygen.

The component comprising the nozzle body 32, the ring channel 35 immediately surrounding it and the ring channel 37 through which the "secondary primary air" flows can be inserted as a whole into the end wall 33 of the combustion chamber 16 or into the gas register 39, 41, 43 to be described and thus also easily replaceable with a corresponding, slightly modified component.

The gas channel 37 for the "secondary primary air" is in turn surrounded by a concentric gas channel 39, this by a further gas channel 41 and finally by a gas channel 43. The corresponding ring openings opening into the combustion chamber 16 are identified by the reference numerals 40, 42 and 44. The annular channels 39, 41 and 43 are flowed through selectively, preferably by air, the blowing in taking place under a pressure of about 200 to 300 mm water column. Before the air exits the annular gas or air inlet openings 40, 42, 44, it is deflected by swirl elements 50, 52, 54 arranged in the region of the openings in the form of baffles and thus set in rotation about the longitudinal axis 14, specifically in the same direction as the "primary primary air" or "secondary primary air" through the swirl elements 46 and 48.

The swirl elements 50 deflect the gas or air flow by approximately 70 °. The swirl elements 52 and 54 deflect the gas or air flow by approximately 40 to 50 ° and 0 to 40 °. All of the swirl elements, in particular the outermost swirl elements 54, can be changed with regard to their angular position and can thus be adapted to the fuel or fuel mixture to be burned.

The flow velocity of the air emerging from the ring opening 40 is approximately 40 m / s at the start of combustion, and approximately 70 m / s at full load. The flow velocity of the air emerging from the ring openings 42 and 44 varies between 0 m / s at the start of combustion and 70 m / s at full load.

The exit velocities of the "primary primary air" and "secondary primary air" remain approximately the same in all operating states between start and full load. Only the discharge quantity or the throughput are changed by correspondingly increasing or reducing the gap widths of the ring openings or ring gaps 36 and 38. The gap widths are changed in the same way. For this purpose, an annular mouthpiece 68 arranged between the two ring openings or gaps 36 and 38 and comprising the two adjacent or facing side walls 62 and 64 of the two ring openings 36 and 38 is in the axial direction or in the direction of the longitudinal axis 14 - and slidably mounted. In the embodiment according to FIG. 1, the ring mouthpiece 68 is used to separate the two primary air channels 35, 37 from one another Pipe jacket 70 connected so that the axial displacement of the ring mouthpiece 68 takes place by appropriate action on the pipe jacket 70. At the start, the ring mouthpiece 68 is shifted to the right in FIG. 1, so that the gap widths of the ring openings 36 and 38 and thus the amount of primary air escaping are a minimum. At full load, the situation is reversed, ie the ring mouthpiece 68 is shifted to the left in FIG. 1, so that the ring openings 36 and 38 are opened to the maximum. The outlet quantity of the "primary" and "secondary" primary air is correspondingly maximum.

The outermost gas or air flow through the ring channel 43 serves primarily to reduce the NO _x content outside the flame in the combustion chamber 16. Furthermore, this flow limits the radial expansion of the flame and prevents deposits on the side walls of the combustion chamber 16.

Powdered fuel, e.g. Carbon powder are blown in, mixed with secondary air or instead of the secondary air. This is particularly possible and expedient at full load when energy peaks occur.

The core of the device according to the invention is the configuration of the nozzle body 32 with the illustrated arrangement of the inlet openings 10 and 12 'for oil and solid fuels. This configuration is now described in more detail with reference to FIGS. 2 to 4.

The fuel inlet is formed by several, namely 16, inlet openings 10, 12 'arranged uniformly distributed over a circumference 11 or 13, the inlet openings 10 for liquid fuel, in particular oil, and the inlet openings 12' for solid fuel or a fuel emulsion alternating are arranged along the circumference. The inlet openings 10 for liquid fuel are directed radially outward along an inwardly offset circumference 13, while the inlet openings 12 'for solid fuel along an outer circumference 11 or closer to the combustion chamber 16 with respect to the longitudinal axis 14 of the combustion chamber 16 in the flow direction are inclined outwards.

Furthermore, a central inlet 18, which extends coaxially to the longitudinal axis of the nozzle body 32 or combustion chamber 16, is provided for blowing in compressed air. A deposit of coal or coal dust on the end face of the nozzle body 32 facing the combustion chamber is thereby reliably avoided. In front of the central compressed air inlet 18 branch lines 20 branch off, which open out at the inlet openings 12 'for solid fuel, specifically in the inlet openings 12' for solid fuel each forming mouthpieces 24 (see Figures 2 and 4). The mouthpieces 24 each comprise a ring 26 with a triangular cross section, an annular edge 28 of this cross section defining or delimiting the inlet opening 12 ′ opening into the combustion chamber 16. In the mouthpieces 24, compressed air channels 30 are provided which are directed towards the inlet opening 12 ′ and are fluidly connected to the above-mentioned compressed air connecting lines or branches 20 within the nozzle body 32. The fluid connection takes place thereby via an outer annular space which is delimited on the one hand by the nozzle body and on the other hand by an annular groove 11 in the mouthpiece 24, the compressed air connecting line or branch opening into this annular space and furthermore several, approximately uniformly distributed over the circumference of the mouthpiece 24, to this annular space Connect the arranged compressed air channels 30 (see Figures 2 and 3).

Due to the relatively pointed or sharp ring edge 28, through which the inlet opening 12 'for solid fuel is limited, the fuel flow is broken up with the formation of a "spray cone". This effect is additionally supported by the injection of compressed air through the compressed air channels 30. By means of the compressed air blown in, the formation of a “spray cone” can be varied or adjusted well to the respectively desired conditions or to the type and quality of the fuel to be burned. As a result of the construction described, the fuel introduced is already distributed over several individual nozzles and additionally extremely "broken open" at these, with the result of a maximum fine distribution and the formation of a maximum free or combustion-active surface.

The mouthpieces 24 are preferably arranged interchangeably in the nozzle body, for example screwed in. This enables adaptation to the fuels to be burned. The different nozzle bodies can differ in terms of inlet openings 12 ′ of different sizes and / or different numbers of compressed air channels 30 or differently dimensioned compressed air channels 30. It is also possible to use mouthpieces 24, the ring edge 28 of which delimits the inlet opening 12 ' is somewhat rounded, stepped or flattened. However, a pointed ring edge 28 is best suited.

The central compressed air inlet 18 can also be arranged within an insert part 19 which can be screwed onto the end face of the nozzle body 32 facing the combustion chamber 16. In this way it is possible to change the free cross-section and the shape of the inlet 18 by using a different insert body 19 (see FIG. 2 in comparison to FIG. 1, where the shape of the inlet 18 corresponds approximately to that of the inlet opening 12 'for solid fuel ).

As already explained, the central compressed air injection through the inlet 18 prevents deposits on the end face of the nozzle body 32 facing the combustion chamber. The centrally recirculating combustion gases, which are around 1500 to 1700 ° C., are deflected there and are carried back into the combustion chamber 16 by the fuel introduced, in particular by the solid fuel introduced through the inlet openings 12 ′. The hot combustion gases cause the same to ignite immediately after the relatively cold fuels or fuel emulsion has escaped, so that the combustion process is started relatively close behind the fuel inlet 12 ′, this ignition being additionally supported - especially during the starting phase the radially introduced oil (through the inlet openings 10). The flame jacket is determined by the equilibrium between the centrifugal forces caused by the rotation as well as the negative pressure caused by the negative pressure prevailing outside the flame jacket in the region of the end wall 33 on the one hand and the counterforce caused by the central negative pressure in front of the nozzle body inside the flame jacket on the other hand. When the combustion starts, the two outer gas and air channels 52, 54 are closed. The ring opening 40 is adjusted so that the speed of the exiting air is about 40 m / s. The annular mouthpiece 68 is - as explained - shifted towards the combustion chamber 16 so that the annular gaps between the side walls 60, 62 and 64, 66 are reduced, whereby the amount of "primary" and "secondary" primary air escapes at a somewhat increased exit velocity is reduced. Due to the somewhat increased exit velocity, in particular of the “secondary primary air” from the ring opening 38 directed towards the introduced fuel, a high break-open effect is obtained. The primary air is divided at the start such that approximately 60 to 70%, preferably 90% of it flows out of the ring opening 36 closest to the fuel inlet and only about 30 to 40% preferably 10% thereof flows out of the second next ring opening 38.

At full load, with an increased total amount of primary air, the ratio between "primary primary air" and "secondary primary air" is about 3: 7. These explanations show that a concentrated, strong gas flow is required in the immediate vicinity of the introduced fuel in order to break it open and thus to start the combustion more easily due to the increased surface area of the fuel. The breaking up of the fuel into the smallest particles or droplets is additionally facilitated by the fact that the fuel is introduced into the combustion chamber through a large number of inlet openings. The relatively compact fuel is therefore already introduced or injected into the combustion chamber in a divided manner, wherein

there is a first break in the area of the inlet openings and a secondary break through the external gas or air flow. The described change in the quantity ratio between "primary" and "secondary" primary air with a simultaneous change in the capacity or discharge quantity as a whole can be obtained in a simple manner by appropriate configuration of the axially movable ring nozzle 68, e.g. as shown in Figure 1 or 5, each with an approximately trapezoidal cross-section.

As has already been explained above, the deflection of the radially outermost individual gas or air flow through the guide vanes or swirl elements 54 is less and can even be zero. This has a considerable influence on the radial expansion of the flame jacket.

The above-mentioned admixture of combustion gases to the "primary primary air" has two advantages. On the one hand, the liquid as well as the solid fuel can be preheated along their paths through the channels 34, 36, 38. On the other hand, a certain amount of afterburning and thus higher efficiency can be achieved. These two advantages outweigh the disadvantage of a lower oxygen content. With pure coal combustion, however, it is advisable not to add combustion gases. Otherwise, the disadvantage of a lower oxygen content could be compensated for by an oxygen enrichment of the other individual gas or air flows (“secondary air”). When a coal-water mixture is burned, wetting agents are preferably added, which ensure an even distribution of the coal particles in the water.

The embodiment according to FIGS. 5 to 7 differs from that according to FIGS. 1 to 4 only by a different structure of the nozzle body. All other measures have remained the same and are also provided with the corresponding reference numerals, so that the description of the nozzle body with reference to FIGS. 6 and 7 can be used below.

The nozzle body 32 according to FIGS. 6 and 7 comprises a central feed line 34 for solid fuels, such as pulverized coal with or without water, oil or the like, a ring line 36 ′ concentrically surrounding this feed line for liquid fuel, such as oil or the like, and this oil ring line Concentrically surrounding compressed air supply 38 'in the form of a plurality of line bores arranged uniformly distributed over a circumference. The feed lines 34 and 36 'for solid and liquid fuel open into radially directed inlet openings 10 and 12, which are alternately distributed evenly over the circumference, as can be clearly seen in FIG. Overall, just as in the embodiment according to FIGS. 1 to 4, eight inlet openings 10 and 12 are provided for solid and liquid fuel.

The compressed air bores 38 ', which extend parallel to the longitudinal axis 14 of the nozzle body 32 or the combustion chamber 16 and which are supplied with "primary primary air" from the gas or air duct 35 immediately surrounding the nozzle body 32, open into one radially open annular gap 22, which lies in the flow direction behind the radially directed inlet openings 10, 12. The annular gap 22 is formed on the end face of the nozzle body 32 attached cover plate 23 is formed, namely, leaving the mentioned, radially extending annular gap 22 (see also Figure 5).

The cover plate 23 has a flat end face 56, while the end face 58 of the nozzle body facing the combustion chamber 16 is frustoconical in accordance with FIGS. 1 to 4. A corresponding design of the end face 56 is of course conceivable.

The "primary primary air" flowing out radially through the annular gap 22, on the one hand, results in a deposit of escaping solid or liquid fuel on the end face 56 and, on the other hand, deposits of fuels or fuel residues on the boundary wall 62 opposite the fuel inlet of the one closest to the nozzle body 32 Gas or air inlet opening 36 'safely avoided. In addition, in the embodiment according to FIGS. 5 to 7, a central compressed air injection can be provided in accordance with the embodiment according to FIGS. 1 to 4.

It is also conceivable to arrange the nozzle body 32 so that it can be pushed back and forth in the axial direction or in the direction of the longitudinal axis 14 within the gas register, whereby on the one hand the gap width of the ring opening 36 for the exit of the "primary primary air" and on the other hand the sinking of the nozzle body and thus the fuel inlet in the end wall 33 of the combustion chamber 16 are changeable or adjustable depending on the constitution of the fuel and the type of fuel.

The outer gas register for secondary air is not necessary for smaller burners.

All features disclosed in the documents are claimed as essential to the invention, insofar as they are new compared to the prior art, individually or in combination.

Claims (28)

1. A method for burning liquid fuels, such as oil or the like, and / or solid fuels, in particular coal, peat or the like, in pulverized form, the latter dry or mixed with a carrier liquid such as water and / or oil as an emulsion together with the liquid Fuel is introduced into a combustion chamber with the formation of a recirculating flow profile and this flow profile is limited by a rotating external air flow, characterized in that the solid and liquid fuels are separated and - when there are several fuel inlets - at a predetermined angular distance from one another along a circumference, in particular along one thought Circumference can be introduced into the combustion chamber. 2. The method according to claim 1, characterized in that both the solid and liquid fuels are introduced into the combustion chamber directed radially outwards with respect to the longitudinal axis of the combustion chamber. 3. The method according to claim 1, characterized in that the solid and / or liquid fuel with respect to the longitudinal axis of the combustion chamber are introduced into the combustion chamber inclined in the flow direction to the outside. 4. The method according to any one of claims 1 to 3, characterized in that compressed air is blown centrally into the combustion chamber. 5. The method according to claim 2, characterized in that the compressed air in the immediate vicinity of the fuel inlet is blown radially into the combustion chamber, the injection preferably taking place approximately uniformly over the circumference of an annular gap or the like. 6. The method according to any one of claims 1 to 5, characterized in that the solid fuels or the fuel emulsion is additionally admixed with compressed air when entering the combustion chamber, preferably immediately before entering the combustion chamber while simultaneously breaking up the supplied fuel. 7. The method according to claim 6, characterized in that the compressed air is directed against the supplied fuel, in particular inclined in the flow direction of the fuel. 8. The method according to any one of claims 1 to 7, characterized in that the outer air flow is blown into the combustion chamber in several concentric partial flows, the partial flows being variable in terms of throughput and decreasing their flow speeds from the inside to the outside. 9. The method according to claim 8, characterized in that at least the fuel inlet closest to the air flow combustion gases are added. 10. The method according to claim 8 or 9, characterized in that at the start of combustion, the air throughput is about 20 to 40% of the throughput at full load. 11. The method according to any one of claims 8 to 10, characterized in that the two air flows closest to the fuel inlet have an approximately constant flow rate in all operating states. 12. The method according to any one of claims 8 to 11, characterized in that the introduction of the air flow adjacent to the fuel inlet ("primary primary air") at an angle of about 10 to 30 °, preferably 15 °, to the radial. 13. The method according to claim 12, characterized in that the radially further outward gas flow ("secondary primary air") is directed so that a directed towards the fuel flow profile, which is approximately hollow-conical, hollow-cone-shaped gas or air Flow profile arises that tries to penetrate and break open the fuel flow profile. 14. Device for burning liquid fuels, such as oil or the like, and / or solid fuels, in particular coal, peat or the like, which in powdered form either dry or mixed with a carrier liquid, such as water and / or oil, as an emulsion together with the liquid fuel therethrough can be introduced through an inlet into a combustion space, said fuel inlet being concentrically surrounded by an air inlet, in particular for implementing the method according to any one of claims 1 to 13, characterized in that the _B uel inlet by a plurality of approximately uniformly over a The circumference, in particular the circumference (11 or 13), of distributedly arranged inlet openings (10, 12 or 10, 12 ') is formed, the inlet openings (10) for liquid fuel and the inlet openings (12 or 12') for solid fuel or fuel emulsion are alternately arranged along the circumference. 15. The apparatus according to claim 14, characterized in that the inlet openings are directed either radially (10, 12) and / or in the direction of flow with respect to the longitudinal axis (14) of the combustion chamber (16) to the outside (12 '). 16. The apparatus according to claim 14 or 15, characterized in that a central inlet (18) is provided for compressed air. 17. The apparatus according to claim 16, characterized in that from the central compressed air inlet (18) or from this leading to the compressed air line (38) connecting lines (20) branch to the inlet (inlet openings 12 ') for solid fuel. 18. The apparatus according to claim 17, characterized in that the connecting lines (20) open at the fuel inlet immediately in front of the inlet openings (12 '), and preferably directed inclined in the direction of flow of the supplied fuel against it. 19. The apparatus of claim 14 or 15, characterized in that an annular gap open in the radial direction (22) is provided as a compressed air inlet, and preferably in the flow direction behind the fuel inlet (inlet openings 10, 12). 20. Device according to one of claims 14 to 19, characterized in that the inlet for solid fuels is formed by a mouthpiece (24) with an inlet opening (12 ') opening into the combustion chamber (16) and through the edge (28) a ring section (26) with an approximately triangular cross section is limited. 21. The apparatus according to claim 20, characterized in that the mouthpiece (24) on the inlet opening (12 ') directed compressed air channels (30) via the connecting line (20) with the central compressed air inlet (18) or leading to this inlet Compressed air line (38) are fluid-connected. 22. Device according to one of claims 14 to 21, characterized in that the solid and liquid fuels and optionally compressed air through coaxially arranged in a nozzle body (32) channels (34, 36, 38) the respective inlet openings (10, 12; 12 ' ; 18, 22) can be fed. 23. The device according to one of claims 14 to 22, characterized in that the air inlet is designed as a register with at least four concentric air inlet openings (36, 38, 40, 42, 44), each air inlet opening having swirl elements (46, 48, 50, 52 , 54) and the annular gap width of the two air inlet openings (36, 38) closest to the fuel inlet are continuously adjustable, while the remaining air inlet openings (40, 42, 44), which are located somewhat further radially from the fuel inlet, can be individually closed or opened. 24. The device according to claim 23, characterized in that a nozzle body (68) comprising the fuel inlet is mounted displaceably in the direction of its longitudinal axis or the longitudinal axis (14) of the combustion chamber (16), but in particular can be brought into a position in which the Fuel inlet is set back or sunk opposite the end wall (33) of the combustion chamber (16). 25. The apparatus of claim 23 or 24, characterized in that the central, the combustion chamber (16) facing the end face of the nozzle body (6S) is either flat (56) or frustoconical (58), spherical cap (convex or concave) conical or the like . 26..Device according to one of claims 23 to 25, characterized in that the annular gap width of the two air inlet openings (36, 38) closest to the fuel inlet can each be changed by changing the relative position of the side walls delimiting the inlet openings (60, 62 and 64, 66) is. 27. The device according to one of claims 23 to 26, characterized in that the annular gap width of the two air inlet openings (36, 38) closest to the fuel inlet can be changed in the same way, namely by shifting one of the two adjacent side walls (62, 64) of the two air inlet openings (36, 38) comprising annular mouthpiece (38) in the direction of the longitudinal axis (14) of the nozzle body (32) or combustion chamber (16), the annular mouthpiece (68) preferably being part of the tube air separating the two partial air flows closest to the fuel inlet. or the like - jacket (70). 28. Device according to one of claims 23 to 27, characterized in that the second nearest air inlet opening (38) opposite the fuel inlet is directed such that the corresponding air flow assumes an approximately hollow-conical flow profile directed towards the approximately conical flow profile of the entering fuel.

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