EP3084300A1

EP3084300A1 - Pulsation burner for the combustion of solid fuels, and method for the operation thereof

Info

Publication number: EP3084300A1
Application number: EP14838778.0A
Authority: EP
Inventors: Tobias Seufert; Helmut Reis; Alexander SCHERRMANN; Hans-Joachim Gehrmann; Helmut Seifert
Original assignee: Karlsruher Institut fuer Technologie KIT
Current assignee: Karlsruher Institut fuer Technologie KIT
Priority date: 2013-12-18
Filing date: 2014-12-15
Publication date: 2016-10-26
Anticipated expiration: 2034-12-15
Also published as: CN106030210B; DE102013114296A1; EP3084300B1; PL3084300T3; WO2015090278A1; CN106030210A

Abstract

The invention relates to a solids burner (1) for a combustion chamber (3) for the combustion of pulverised solid fuels (11), and to a method for the operation thereof, having a primary air feed device and a fuel feed device for producing an air/fuel mixture composed of primary air (11) and fuel (10), and having at least one lance (5) which transports the air/fuel mixture to a mouth opening (2). To enable the solids burner (1) to be operated with low nitrogen oxide emissions, there is provided upstream of the mouth opening (2) a control device (23) which adjusts a content of fuel (10) contained in the air/fuel mixture in pulsating fashion over time.

Description

Pulsation burner for burning solid fuels and method for its operation

The invention relates to a solid fuel burner for a combustion chamber for the combustion of pulverized, solid fuels and a method for its operation with a Primärluftzufuhreinrichtung and a fuel supply device for producing a

Air / fuel mixture of primary air and fuel and at least one of the

Air / fuel mixture to a mouth-carrying lance.

From EP 005 438 A1 an apparatus and a method for ignition and

Maintaining a combustion process of pulverized, supplied in a carrier gas flow of a combustion zone coal known. It is proposed to improve the ignition and the combustion of combustion, to supply a varying range of a mixture of oxygen and coal in a combustion zone. An environmentally relevant generation of the mixture is not disclosed.

From the Austrian patent no. 243167 a device for controlling the supply of fuel and combustion air in burner systems for achieving a pulsating combustion is known.

French Patent No. 795 933 discloses a mixing device arranged in an air stream with pulverized coal, in which two propellers rotating freely against each other are used for improved homogenization of the air / coal mixture.

A solid fuel burner is known from EP 1 312 859 A1, in which a solid, pulverized fuel such as lignite and primary air are mixed and supplied to a combustion chamber in a lance and incinerated there. To accelerate the combustion air is additionally introduced via an additional supply in the lance. For example, due to alternative energy sources, such solid fuel burners are variably operated with respect to their power to be provided, that is to say partially operated under partial load conditions. In this case, the fuel supply is preferably throttled, so that partially incomplete combustion processes occur with unstable ignition processes. This results in high pollutant loads, especially high levels of nitrogen oxides (NO _x ).

The object of the invention is the development of a solid fuel burner with reduced emission values, in particular in a partial load range. Furthermore, it is an object of the invention to propose a method for operation of a solid fuel burner, which enables the emission of lower pollutant emissions.

The object is solved by the subject matter of claim 1. The one of this

dependent claims give advantageous embodiments of the subject matter of claim 1 again. Furthermore, the object is achieved by the features of the method of claim 12. The dependent of the claim 13 claim is an advantageous embodiment of the method of claim 13 again.

The proposed solid fuel burner is preferably used in power plants for power generation via steam turbines, for example in conjunction with power / heat couplings. By means of the proposed solid fuel burner and the proposed method for its operation whose operation can be operated with less pollutant development in particular with lower NOvKonzentrationen especially in partial load operation and thus averaged or integrated over the entire operation. For example, to achieve and comply with partially legally prescribed limits necessary funds, such as SCR catalysts for denitrification and the like can be saved or used to a reduced extent, so that a cost-saving operation of the solid fuel burner can be provided. The solid fuel burner is in this case preferably suitable in power plant processes with a supply of the fuel by means of a lance at an orifice opening into the combustion chamber. This occurs in contrast to grate firing by low excess air in the combustion chamber with air ratios of, for example, 1, 4 and temperatures of 1200 ° C and more high NO concentrations, which are particularly effectively reduced by the proposed solid fuel burner in these environments.

In detail, the proposed solid fuel burner and the proposed method for its operation for power plants with orifice-opening burners solve the following subtasks: Firstly, a low CO emission level can be achieved with variable load.

At the same time, that is alternatively or additionally, NOvEmissions can contribute to

Different load cases are reduced by pulsation to low NOvKonzentrationen, for example, under a quarter of the NCvKonzentration a non-pulsating operated solid burner under otherwise identical conditions. The

Heat transfer to the boiler at variable load can be improved by increasing the combustion intensity.

In this case, a particularly good flame stability can be achieved during pulsating operation, when a swirl burner is used as a solid burner whose flame guidance by a circular flow of the fuel and primary air supply, for example is stabilized by means of a arranged around the mouth opening, circularly supplied secondary air supply.

It has proven particularly advantageous if a frequency of a pulsation such as

Pulsation frequency of the solid fuel burner between 0.5 Hz and 1 Hz is provided. In this range, a minimum of the NOv emissions occurs at almost constant low-level CO concentrations. Among other things, the pulsation frequency is dependent on the particle size and its particle distribution of the fuels and their loading, so that a corresponding adaptation of the pulsation frequency to these changes and correspondingly changed pulsation frequencies beyond the mentioned frequency range are included in the inventive idea.

In addition to the reduction of load and emissions can be proposed in the proposed

Solid fuel burner combustion intensity and the flame volume can be increased, which means a significant improvement in the heat transfer conditions. This can represent an advantage in large combustion chambers, especially at partial load.

Due to the pulsating operation of the proposed solid fuel burner, a delayed mixture of oxidizing agent in the form of the supplied primary air and optionally supplied secondary air and the fuel may arise. This can lead to an expansion of the flame body and improve the heat output over the layer thickness of the flame. This is a significant advantage especially at partial load in power plant processes. The formation of NO _x is thereby reduced, the combustion intensity and combustion efficiency increased.

Specifically, the fixed burner proposed for a combustion chamber for burning pulverized solid fuel includes a primary air supply device such as a volumetric fan, a draft fan or the like. For introducing solid, pulverized fuel into the primary air guided in the primary air supply device, a fuel supply device, for example a metering device monitoring the volume and / or weight of the fuel, such as supply flaps, metering shafts, screw conveyors and / or the like, is provided. The fuels may be formed from lignite, hard coal, organic material, mixtures thereof, and the like. A control unit is used to set a content of fuel in the primary air, that is a setting of a mixture of fuel and air, for example, a predetermined amount of fuel based on a volume unit of the primary air by means of a metering device of the fuel and / or the primary air. The air / fuel mixture is transported to an orifice via at least one lance, for example a metering or feed tube, a feed channel or the like of the solid fuel burner. The Mün- opening opens into a spherical, cylindrical or freeform combustion chamber with an ignition of the air / fuel mixture, so that after ignition from the mouth opening extending into the combustion chamber flame is formed, which heats a combustion chamber surrounding or connected boiler such as steam boiler , The emissions produced during combustion are emitted via an exhaust gas opening, for example a chimney, chimney or the like. In this case, an exhaust gas purification device can be connected upstream. By reducing the resulting emissions such, possibly existing

Emission control device operated more efficiently.

To reduce emissions such as pollutants, in particular NO emissions and CO emissions is at least in a partial load range of

Solid burner in a stream of the air / fuel mixture upstream of the mouth opening, a control device is provided which sets a content of fuel contained in the air / fuel mixture over time pulsating. This means that, over time, the content of fuel in the air / fuel mixture varies in a cyclically varying manner.

In an advantageous embodiment, a control device is provided, which pulsatingly enriches and depletes a content brought up constantly in the air / fuel mixture. Such a control device may be formed for example from a provided on the lance in front of the mouth opening, pulsating fuel from the air / fuel mixture receiving and donating baffle plate. For example, it has proved to be advantageous to adjust the flow at such a baffle plate so that fuel deposits on less fueled areas due to turbulence on the baffle plate and the deposited fuel dissolves again due to the flow geometry changing depending on the deposited fuel. It has surprisingly been found that a substantially planar design of the baffle plate can form this control device. In order to make an adjustment of the baffle plate, for example, this can be arranged to be displaceable relative to the lance in which the air / fuel mixture is guided, for example radially displaceable. In this way, the cross section of the lance may be formed mechanically adjustable, for example, from the outside. The diffuser can be actuated automatically, for example, be displaced radially or eccentrically to a cross section of the lance in a relation to the lance fixedly mounted frame. In specially trained

Embodiments may be the diffuser to achieve the pulsating effect be controlled automatically in an intended or predetermined by an electronic control frequency, for example, between 0.5 Hz and 1 Hz.

In a further advantageous embodiment of the content of fuel in the primary air on and depleting control device can be provided to operate the metered amounts of the fuel pulsating by the controller on the fuel supply means the fuel supply in the primary air sets pulsating. For this purpose, appropriate metering devices can be provided which meter in the proposed Pulsationsfrequenz- range and decreasing amounts of fuel to form pulsating levels of the fuel in the primary air stream. For this purpose, for example, a control device made of a pulsed fuel-loaded soulless screw equipped fuel supply has proven to be advantageous. In this case, for example, different amounts of fuel are metered in each case between two screw windings and the screw is rotated with constant rotational movement, so that time-dependent quantities of fuel are introduced into the primary air flow at an outlet shaft of the screw. Alternatively, a distance such as the axial spacing of turns of the worm can be dimensioned such that a distance is set between a fuel dose transported by a turn to the fuel dose transported by the next turn, so that the individual fuel cans are arranged successively in the pulsation frequency the primary air flow are introduced. Alternatively, the screw can be filled evenly and its rotational movement can be varied over time. In this way, a temporally cyclically varying content of fuel in the primary air flow is achieved.

Alternatively or in addition to a pulsating enrichment and depletion of the contents of fuel, a control device may be provided, which sets the primary air supply pulsating at the primary air supply device. In this case, a metered amount of the fuel can be kept constant or, in addition to the amplification of the pulsating effect, can also be made pulsating in the same phase. In this sense, a corresponding control device for a pulsating quantity metering of the fuel in the primary air flow and a control device for pulsating control of the primary air flow is provided. For controlling the pulsating operation of the primary air, the control device can control, for example, corresponding supply blowers, primary air cross sections, louvers, valves or the like in a pulsating manner.

In a further advantageous embodiment, coaxial to the at least one lance with a primary air supply, a further lance for supplying fuel in an air stream, a carrier gas or the like with a relation to the primary air flow same, a higher or reduced gas flow can be provided, wherein in at least one of Lances a pulsating operated gas flow is entered into the mouth opening and at least by means of a lance of the fuel through the mouth opening is entered into the combustion chamber.

Furthermore, arrangements of preferably coaxially arranged lances may be provided, wherein at least one fuel introduced in a lance is coal and in the case of different fuels a fuel is organic solid, for example solid or solidified and pulverized biomass. Dusty carbon advantageously have particle size distributions d _p of 50 μηι to 1 10 μηι. Alternative, for example, the coal admixed or additional, for example, supplied by means of a separate lance fuels, for example, up to 20% of

Combustion heat to be burned and a d _p so from 1 mm to 4 mm

exhibit. In the case of several fuels supplied via separate lances, the

Be provided fuel supply of the coal and / or the alternative fuel pulsating.

It has proved to be advantageous to set a frequency of a pulsating content of fuel greater than or equal to 0.5 Hz and less than or equal to 1 Hz. In the proposed method, the proposed solid fuel burner is operated in a pulsed manner by metering solid, pulverized fuel into the combustion chamber pulsating at a frequency between 0.5 Hz and 1 Hz. The method can be used in a full load operation to improve the

Pollutant emissions, especially nitrogen oxides, a pulsating operation of

Provide solid fuel burner. However, in a preferred manner, the method is carried out in a pulsating manner exclusively during a partial load operation, so that the solid fuel burner is preferably operated pulsating exclusively in a partial load range.

The invention will be explained in more detail with reference to the embodiment shown in Figures 1 to 6. Showing:

FIG. 1 shows a schematic side view of a solid fuel burner,

FIG. 2 shows a schematic illustration of a fuel supply device,

FIG. 3 shows a diagram of a pollutant development as a function of a pulsation frequency of a solid fuel burner,

FIG. 4 a shows a reducer of the lance in the air / fuel mixture,

Figure 4b, the reducer of Figure 4a along the section line A-A with attached

Controller,

4c shows the reducer of FIGS. 4a, 4b in a 3D view, FIG.

FIG. 5 shows the control device of FIGS. 1 and 4b in a view from the transverse direction. cut the lance of the extended lens in a schematic representation and

Figure 6 shows the control device of Figure 5 in view with retracted in the cross section of the lance lens in a schematic representation.

1 shows a schematic side view of the arranged at the mouth opening 2 of the combustion chamber 3 only partially with the lining 4 solid burner 1. The solid fuel burner 1 has three coaxially arranged, by means of the spacers 8, 9 mutually supported lances 5, 6, 7 , By means of which gas streams and fuel introduced through the mouth opening 2 in the combustion chamber 3 and after ignition by means of an ignition device, not shown, for example, a continuous combustion operation hedging pilot burner, are burned. In the illustrated embodiment, the primary air is supplied with the primary air 1 1 and the solid fuel 10 fluidized therein, represented by the arrow 14, for example, from a riser 26, (Figure 2) by means of the radially outer lance 5, symbolized by the arrows 12, so that an introduction of the fuel 10 at the mouth opening 2 takes place in the form of an annular gap. In the central lance 5, in addition to the fuel contained in the primary air 1 1, another solidified in a gas stream such as air flow solid fuel, for example, pulverized biomass or the like in the combustion chamber 3, symbolized by the arrow 13 are introduced. In the lance 7 lying radially between the lances 5, 6, gas for a support flame can be introduced into the combustion chamber 3 via a further annular gap, symbolized by the arrows 15.

The solid fuel burner 1 is designed as a swirl burner. For this purpose, the secondary air supply in the direction of the arrow 16 is supplied radially outside the lances 5, 6, 7, wherein the swirl generator 17, for example a fan or the like at the annular gap 18 generates an air swirl in the direction of the arrows 19, so that the gas and fuel streams of the lances 5, 6, 7 tangentially symbolized at the mouth opening 2 by the arrows 20 are introduced into the combustion chamber 3.

In particular, in a partial load range of the solid fuel burner 1, the supply of

Fuel 10 pulsating, preferably in a pulsation frequency between 0.5 Hz and 1 Hz. For this purpose, the baffle plate 21 is inserted into the flange 22 in the embodiment shown in front of the mouth opening 2 in the lance 5. For a given primary air flow accumulates cyclically at the baffle plate 21 fuel 10 and is replaced after a successful enrichment again, so that a charge of the combustion chamber 3 with cyclically in the proposed pulsation frequency changing levels of fuel 10 takes place. overall According to a further approach, a pulsating adjustment of the contents of fuel by means of a set on the baffle plate 21 dynamic flow behavior of the fuel / air mixture is generated. The pulsation frequency is dependent on a particle size distribution and a loading of the primary air flow, ie an average content of fuel 10 in the primary air 1 1, which is preferably below a typical content of fuel 10 at full load. When using coal as fuel 10, for example, particle size distributions d 50 have been advantageous

50 microns and 110 microns proved to be advantageous. In this sense, the baffle plate 21 forms the control device 23 for producing a pulsating content of fuel in the primary air 11.

FIG. 2 shows a control device 23a, which is modified with respect to the control device 23, for the pulsed operation of a solid fuel burner, for example, similar to the solid fuel burner 1 of FIG. 1, without a baffle plate. The control device 23a is formed by the metering device 24, the time-varying amounts of fuel such as fuel cans 25 of the fuel 10 in the leading to the solid burner riser 26, in which the primary air 1 1 is performed introduces. For this purpose, the metering device 24 is designed as a soulless screw 27, which is rotated at a predetermined rotational speed about the axis of rotation d. The distance a between the turns 28 of the screw 27 is dimensioned such that when the screw 27 is continuously filled between the fuel cans 25 entrained by a turn 28 and the turns 28 in the transport direction, the distance b is set, whereby a time-varying addition fuel cans 25 into the riser 26 takes place. The speed of the screw 27 can be adapted to a desired loading of the primary air 1 1 with fuel 10 to achieve a desired frequency such as pulsation frequency of the content of fuel 10 preferably in the range of 0.5 Hz to 1 Hz. When the solid fuel burner is operated at full load, the distances b are also filled with fuel 10 due to the increased fuel cans 25 between two windings, so that a continuous charging of the riser pipe 26 with fuel 10 takes place. FIG. 3 shows the diagram 30, measured for example by means of a solid burner 1 corresponding to FIG. 1, with the contents c [NO _x ] of nitrogen oxides and c [CO] of carbon monoxide of the exhaust gas as a function of the frequency F [Hz], such as pulsation frequency between 0 and 1 2 Hz of a varied content of solid pulverized fuel 10 (FIGS. 1 and 2). The broad bars 31-35 indicate the contents of nitric oxide and the narrow bars 36-40 the contents of carbon monoxide. The contents of carbon monoxide are largely independent of the frequency F at a low level, for example, between 3 and 4 mg / Nm ³ based on 5 percent by volume of dry oxygen, so that no negative influence of the pulsating Operation of the solid fuel burner 1 starts on the sufficiently low levels of carbon monoxide. In the embodiment shown fall the

Nitrogen oxide contents in the range of the frequencies F = 0 at the beam 31, ie at non-pulsating solid fuel burner 1, and a frequency F = 1, 2 Hz at the beam 35 to a minimum - here at the frequency F = 0.8 significantly from one operation at Non-pulsating solid fuel burner 1, for example, about 500 mg / Nm ³ based on 5

Volume percent of dry oxygen at nitrogen oxides bar 31) to partially below 20 percent of this content to, for example, 120 mg / Nm ³ based on 5 percent by volume of dry oxygen to nitrogen oxides (bar 33) The graph 30 shows the measurements on the combustion chamber 3 of Figure 1 with the Solid fuel burner 1 basis. In other

Burning environments may experience changed readings and other frequencies may be advantageous for a minimum level of nitrogen oxides.

FIGS. 4a to 4c show, in an overview, the reducing piece 41 of the lance 5 of FIG. 1 in a view against the flow direction of the air / fuel mixture (FIG. 4 a), a longitudinal section along the flow direction along the section line AA with a control device 23 (FIG. 4 b) and in 3D view (Figure 4c). The

Reducer 41 has two pipe sections 42, 43 with different diameters D1, D2, for example about 150 mm and 70 mm. At the larger diameter D1, the opening 44, for example, with a diameter D3 of about 40 mm to 45 mm for receiving the riser for introducing the air / fuel mixture in the lance 5 and then introduced into the combustion chamber 3. The distance A1 of the center of the opening

44 to the end of the pipe section 42 is approximately 65 mm. The lengths L1, L2 of

Pipe sections 42, 43 are about 1 15 mm and 50 mm. The length L3 of the middle section

45 between the two pipe sections 42, 43 is approximately 140 mm. The radii R1, R2 at the junctions between the pipe sections 42, 43 and the middle section 45 are 80 mm and 90 mm. The opening angle α of the central portion 45 is 30 °. Between the two radii R1, R2, a frusto-conical region 46 with a length L4 of approximately 33 mm is provided. The end 47 is concentrically provided on the pipe section 42 to the flow axis ds the opening 47, through which the lances 6, 7 (Figure 1) are guided. The lances 6, 7 limit at the end-side flange 48 of the pipe section 43 an annular gap 49, only indicated here, through which the air / fuel mixture flows to the

Outlet opening 2 (Figure 1) is guided. Due to the nature and design of the Reduzierstücks 41, the line of the air / fuel mixture to the mouth opening 2 takes place with swirl and can be done by the control device 23 pulsating by time-varying deposited on this fuel and taken back. It is understood that the Forming the reducer 41 with respect to the illustrated embodiment may also have other dimensions.

The control device 23 consists in the embodiment shown in the

Diffuser 21 with the central opening 51 which is guided radially displaceable between the flanges 22 with respect to the flow axis ds. To set the eccentric displacement of the lens 21 relative to the annular gap 49, for example, the adjusting screw 50 is provided here. In the embodiment shown here, the lens 21 closes the upper part of the annular gap 49, while the lower part of the annular gap 49 remains open. As a result of the twist, a pulsating equilibrium between deposition and removal arises on the surface F1 of the surface projecting into the annular gap 49

Diffuser 21 a. The area F1 can, for example, for setting the

Balance, for adjusting the Pulsationsfrequenz and the like by eccentric displacement of the lens 21 can be adjusted.

FIGS. 5 and 6 show a view of the control device 23 of FIGS. 1 and 4b with the diffuser 21 (FIG. 5) not engaging in the annular gap 49 and with the surface F1 set in the annular gap 49 (FIG. 6). The diffuser 21 is in the flanges 22,

For example, a frame made of metal or the like guided radially displaceable. The free opening 51 substantially corresponds to the outer diameter of the annular gap 49, which is bounded radially inwardly by the outer diameter of the lance 7, which is shown only schematically. The lance 6 shown radially inside the lance 7 according to FIG. 1 is not shown. In FIG. 5, the scattering plate 21 is retracted, so that the entire annular gap 49 is free. Such a setting can be set, for example, in full load operation of the solid fuel burner 1 (FIG. 1). At least in partial load operation is the

Streublende 21 according to Figure 6 eccentrically displaced in the annular gap 49, so that a pulsating supply of the fuel to the mouth opening 2 (Figure 1) occurs. The

Displacement of the lens 21 can be done automatically by means of the screw 50 of Figure 4b manually or otherwise by means of an actuator automated. For example, the area F1 may be adjusted depending on the flow of the air / fuel mixture, the particle size of the fuel, its content in the stream, the content of the exhaust gas of NOx and / or CO, the load operation and / or the like by such an actuator become. LIST OF REFERENCE NUMBERS

Solid fuel burner

mouth

combustion chamber

lining

lance

spacer

fuel

primary air

arrow

swirl generator

annular gap

arrow

baffle plate

flange

control device

metering

fuel dose

riser

slug

convolution

diagram

bar

bar 5 bars

6 bars

7 bars

8 bars

9 bars

0 bars

1 reducer

42 pipe section

43 pipe section

44 opening

45 middle section

46 area

47 opening

48 flange

49 annular gap

50 set screw

51 opening

A-A Section line A1 Distance a Distance b Distance

D1 diameter

D2 diameter

D3 diameter d rotation axis ds flow axis

F frequency

F1 area

L1 length

L2 length

L3 length

L4 length

R1 radius

R2 radius α opening angle

Claims

claims

1. solid fuel burner (1) for a combustion chamber (3) with an exhaust port for combustion of pulverized solid fuels (10) with a Primärluftzufuhreinrichtung and a fuel supply device for producing an air / fuel mixture of primary air (11) and fuel (10) and at least one a stream of

Air / fuel mixture to a mouth (2) transporting lance (5), characterized in that upstream of the orifice (2) a control device (23) is provided, which by means of a pulsating over time operation of the content contained in the air / fuel mixture reduced at fuel (10) NOvEmissionen at the exhaust port.

2. solid fuel burner (1) according to claim 1, characterized in that the control device (23, 23 a) in the air / fuel mixture constantly brought up content of fuel (10) pulsating and depleted.

3. solid fuel burner according to claim 1 or 2, characterized in that the control device on the primary air supply means the primary air supply sets pulsating.

4. solid fuel burner (1) according to one of claims 1 to 3, characterized in that the control device (23a) adjusts the fuel supply to the fuel supply pulsating in the primary air.

5. solid fuel burner (1) according to one of claims 1 to 4, characterized in that a frequency (F) of a pulsating adjustment of the content of fuel (10) is greater than or equal to 0.5 Hz and less than 1 Hz.

6. solid fuel burner (1) according to one of claims 1 to 5, characterized in that the control device (23) from a at the lance (5) provided, pulsating fuel (10) from the air / fuel mixture receiving and donating baffle plate (21) is formed.

7. solid fuel burner (1) according to claim 6, characterized in that by means of a relative to the lance (5) displaceable baffle plate (21) has a cross section of the lance (5) is adjustable.

8. solid fuel burner (1) according to claim 7, characterized in that the baffle plate (21) is received in a frame radially displaceable relative to the lance (5).

9. solid fuel burner (1) according to one of claims 1 to 8, characterized in that for generating a swirl upstream of the control device, a reducer (41) is provided with a pipe section (42) of large diameter (D1) and a pipe section (43) of smaller diameter (D2) and a diameter difference between these compensating middle portion (45), wherein on the pipe section (42) with large diameter ( D1) is provided an opening (44) for supplying the air / fuel mixture.

10. solid fuel burner (1) according to one of claims 1 to 9, characterized in that the control device (23a) is formed from the with a pulsating fuel (10) fed soulless screw (27) equipped with fuel supply.

1 1. solid fuel burner (1) according to one of claims 1 to 10, characterized in that coaxially to the at least one lance (5) at least one further lance (6, 7) is provided for supplying a gas stream and at least one of the lances (5 ) Pulsing fuel (10) in the mouth opening (2) brings.

12. solid fuel burner (1) according to claim 1 1, characterized in that at least one fuel (10) is coal and in different fuels, a fuel is organic solid.

13. A method for operating a solid fuel burner (1) according to any one of claims 1 to 12, wherein the fuel (10) is metered pulsating at a frequency between 0.5 Hz and 1 Hz in the combustion chamber (3).

14. The method according to claim 13, characterized in that the solid fuel burner (1) is operated pulsed exclusively during a partial load operation.