WO2013182214A1 - Method for operating a multi gas burner and multi gas burner - Google Patents

Abstract

The invention relates to a method for operating a multi gas burner comprising at least one burner lance with a first, second and third nozzle, and further comprising a first, second and third supply chamber. For a high-calorific operation, air is fed via the first nozzle, 0₂-depleted gas is fed via the second nozzle and the high-calorific fuel gas is fed via the third nozzle into the combustion chamber and all are combusted therein. The invention further relates to a multi gas burner for operation with a low-calorific and high-calorific fuel gas.

Description

 Method for operating a multi-gas burner and multi-gas burner

The invention relates to a method for operating a multi gas burner and a multi gas burner for operation with a low and a high calorie fuel gas.

Generic multi-gas burners usually have a combustion chamber and at least one burner lance. This burner lance is configured with a first, a second and a third nozzle. Furthermore, a first, a second and a third supply chamber are provided, which are fluidically connected for supplying gases into the combustion chamber, each with a nozzle. The nozzles of the at least one burner lance terminate on one side in the combustion chamber and on the other side in a respective feed chamber. Furthermore, a burner muffle is provided in the combustion chamber in the region of the end of the nozzles. A burner with several burner lances is referred to as a multi-lance burner.

Generic burners are known for example from DE 196 27 203 C2 and DE 42 08 951 C2.

Such gas burners are used in hot gas generators, which serve to heat process gases, for example in the context of the smelting of iron ores. For a grinding-drying process of coal hot process gases are needed. The ground and dried coal continues to be used in the smelting of iron ores. As fuel gases for hot gas generators are usually low calorific gases, which are also referred to as lean gases, with an oxygen carrier for combustion, especially air, passed through the nozzles in the burner chamber, where they are then mixed with the oxygen carrier, ignited and burned , In order to increase the flexibility and usability of hot gas generators, it is desirable to be able to alternatively operate the burner or burners of the hot gas generators with other fuel gases, such as high-calorie fuel gases.

Due to the higher calorific value of the high-calorie fuel gases, they burn with a higher flame temperature compared to the low calorific gases. It should be noted that from combustion temperatures above about 1300 ° C by a thermal conversion of the N _2, the oxygen carrier for the combustion, especially in normal air, NO _{x is} formed. The combustion temperatures with the use of high-calorie combustion gases are usually above this critical temperature range. However, a formation of NO _x must be largely avoided due to environmental protection regulations.

It is therefore the object of the invention to provide a method for operating a multi-gas burner and such a multi-gas burner, with which the combustion of high-calorie fuel gases is possible in compliance with the applicable environmental protection regulations, in particular in combination with coal grinding plants.

This object is achieved by a method for operating a multi gas burner with the features of claim 1 and a multi gas burner with the features of claim 10.

Further advantageous embodiments are specified in the dependent claims, the description and the figures.

According to claim 1 it is provided that a multi-gas burner with at least one burner lance with a first, a second and a third nozzle, with a first, a second and a third feed chamber, which are each fluidly connected to a nozzle and with a combustion chamber in the the at least one burner lance protrudes, is operated such that in a high-calorie operation at the same time via the first nozzle air, via the second nozzle 0 ₂ -depleted gas and the third nozzle a high-calorie fuel gas are introduced into the combustion chamber and there to the reaction, in particular burned using the air and 02-depleted gas as oxygen suppliers or oxidizers for combustion.

The invention is based on the finding that, in order to avoid the formation of ΝΟχ, it is necessary to lower the flame temperature such that it lies below a range in which NO _x can be generated to the greatest possible extent. This temperature range is below about 1300 ° C.

This can be achieved according to the invention by carrying out the combustion at elevated λ values in comparison to a low calorie operation, that is to say a combustion of a low calorie combustible gas. The λ value is also referred to as the combustion ratio or air ratio and describes the ratio of supplied oxygen suppliers for the combustion, in particular air, to the stoichiometrically required for the combustion of the fuel gas minimum amount of air.

If, during combustion of a high-calorie gas, the combustion is carried out with more combustion air, that is to say with a larger amount of oxygen suppliers for the combustion, then the λ value increases. The additional introduction of more combustion air, the resulting gases are cooled in a complete combustion of the fuel gas. In this way, it can be achieved that the entire combustion process takes place at a temperature which is below the critical temperature range for NO _x formation.

Conventionally, oxygen is used by the oxygen supplier for the combustion of normal outside air with an oxygen content of about 21%. Due to the higher amount of oxygen suppliers for combustion, the oxygen content in the hot process gas increases. This is particularly problematic when the gas burner is used in a hot gas generator, which is used to produce process gases for coal grinding plants. Such coal grinding plants are used, for example, for the spreading of carbon carriers, such as coal, for blowing in blast furnaces with the Pulverized Coal Injection (PCI) method or in the context of coal gasification plants. In such systems, the process gas must have an oxygen content of less than 10% due to the explosion protection. Therefore, it is not possible by increasing the λ value to allow the use of high-calorie fuel gases. The same problem exists with many process gases used in explosive environments. Thus, in addition to the prevention of NO _x , it is imperative for the use of high-calorie fuel gases to ensure that the resulting hot process gas has an oxygen content which is below a percentage determined depending on the process.

Therefore, a further basic idea of the invention may be seen as not using exclusively normal air as the oxygen supplier for the combustion, but mixing the oxygen supplier for the combustion of normal air and 0 ₂ -depleted gas. As a result, the oxygen supplier used for combustion has a lower oxygen content than normal air. As a result, the burner can be operated with higher λ values, so that the necessary lowering of the flame temperature described above is made possible. However, due to the lower oxygen content of the oxygen supplier for combustion used in this way, it can nevertheless be achieved that the resulting process gas has a reduced oxygen content, in particular less than 10%, so that the process gas can be used, for example, in coal grinding plants.

In an advantageous embodiment of the method, it is provided that in a low calorie operation simultaneously via the first nozzle air as oxygen supplier for the combustion and the second nozzle a low-calorie fuel gas are passed into the combustion chamber and there for reaction, in particular for burning, brought , This makes it possible to operate a multi-gas burner with both a low-calorie fuel gas as well as a high-calorie fuel gas and not have to provide their own burner for each of these modes.

This embodiment is based on the finding that the nozzle which is used in the low calorie operation for the low calorie fuel gas is not used in high calorie operation. Therefore, this nozzle can be used to mix 0 ₂ depleted gas to the air from the first nozzle to provide the oxygen source for combustion. The advantage of this solution over providing a further nozzle for the 02-depleted Gas is that thereby the burner lances used, for example, need only three and not four nozzles. This reduces in particular the overall depth and size of a multigas burner consisting of one or more such burner lances.

It is preferred if an outer nozzle is selected as the first nozzle, a middle nozzle as the second nozzle and an inner nozzle of the burner lance as the third nozzle. Thus, regardless of low calorie or high calorie operation, air is always blown into the combustion chamber through the outer nozzle. The fuel gas is blown in the low calorie operation through a central nozzle, so that the fuel gas is blown out of the nozzle surrounded by the injected air and is mixed well with this and can react. Similarly, this is also the case in high calorie operation where the inner nozzle is used to inject the high calorific fuel gas. By using the center nozzle for the 0 ₂ depleted gas, it is also possible here that the high-calorie fuel gas injected through the inner nozzle can mix well with the oxygen supplier for the combustion, which consists of air and O ₂ -depleted gas.

In the combustion of low calorific gases, preference is given to having λ values in the range from about 1.05 to about 1.2. Due to the low calorific values, between 2000 kJ / iriN ³ and 4000 kJ / rriN ³ , the combustion temperatures are below 1300 ° C. As previously stated, in a high calorific operation, the multigas burner must be operated at higher λ values in order to achieve the necessary lowering of the flame temperature. Depending on the calorific value of the high calorific gas used, the λ values are in the range of approximately 1.5 to approximately 2.0. For example, in the combustion of coke gas, the λ value is preferably in the range of 1.6, with between 15% and 30% of the oxygen source for combustion being O2 depleted gas.

In order to enable the use of the resulting process gas in coal grinding plants or other explosion-critical processes, the λ-value in low calorie operation and the λ value and admixture of O2-depleted gas in high-calorie operation is set such that the generated hot process gases, also known as Hot gases are called, an O2 content of less than 10%. If it is necessary due to explosion protection guidelines, a lower target value of O ₂ content in the hot process gas can also be achieved by a corresponding adaptation of the admixture of O ₂ -depleted gas.

In low calorie operation, this can be achieved by the comparatively low calorific value of the low-calorie combustible gas without much effort.

In high calorific operation, depending on the selected λ value, it is necessary to add sufficient O ₂ depleted gas as part of the oxygen supplier for combustion. The exact ratio of air to 0 ₂ -depleted gas in the oxygen carrier for the combustion depends essentially on the exactly used high-calorie fuel gas and the then used λ value. This also makes it possible to achieve oxygen levels in the generated process gas, which are well below 10%.

Furthermore, it is provided that the amount of the fuel gas, the λ-values and the composition of the oxygen supplier for the combustion of air and 0 ₂ -depleted gas are adjusted so that the measured flame temperature does not exceed a value of about 1300 ° C. Here, the λ value is determined substantially by the amount, that is, the flow rate per unit time, the fuel gas and the amount of the oxygen supplier for the combustion, since the shares of the oxygen supplier for the combustion, which do not react with the fuel gas, for cooling and Lowering the flame temperature contribute.

In an advantageous embodiment of the method, a recirculated process gas, for example from a grinding-drying process, in particular from a coal grinding plant, is used as the O ₂ -depleted gas. In a grinding operation of carbonaceous solid fuels with air transport, as is the case for example in vertical roller mills with air flow promotion, a gas must be used as the process gas, which has an oxygen content of less than 10%. Often, in this case, a so-called mill drying is carried out in which the coal to be ground or another starting material is also dried in addition to comminution. For this purpose, as already stated, hot process gases are necessary, which however, for reasons of explosion protection, have an oxygen content of less than 10%. must have. These process gases can be diverted from the grinding operation as 02-depleted gases for the operation of the multi-gas burner. If the hot process gases generated by the multigas burner are used for grinding drying, then they are then led back into the grinding process, so that in the total sum no 02-depleted process gas is withdrawn from the grinding process. Of course it is also possible to use 02-depleted gas from other sources.

In an advantageous embodiment, coke oven gas is used as the high calorific gas and blast furnace gas is used as the low calorific gas. Often coal pulverizers are combined with a hot gas generator constructed of a multi gas burner in ore processing and processing, e.g. Smelting processes, used. At the upper edge of the blast furnace, blast furnace gas is produced, which is available as a favorable fuel for the mill drying and the operation of the burner. As high-calorie fuel gases any fuel gases, such as synthesis gas, coke gas or natural gas can be used. The low calorific gas can also be referred to as lean gas and the high calorific gas as rich gas. If reference is made to air in the context of the invention, this may be understood as meaning, in particular, normal outside air having an oxygen content of about 21%. As oxygen supplier for the combustion, those gases are referred to within the scope of the invention which are supplied to the fuel gas during the combustion process. Alternatively, the oxygen carrier or supplier for combustion may also be referred to as combustion air.

In the context of the invention, a gas having a calorific value or calorific value in the range from about 2,000 to about 4,000 kJ / m.sup.3 _N ³ and a high-calorific gas from a gas of calorific value or calorific value in the range from about 10,000 to about 10,000 kW can be used for a low-calorie gas about 40,000 kJ / m _N ^{3 are} considered. It is not essential for the invention, which calorific values have the low calorific and the high calorific gas, but that the high calorific gas has a higher calorific value than the low calorific gas.

Furthermore, the invention relates to a multi-gas burner for operation with a low and a high-calorie fuel gas. For this purpose, a generic burner with a combustion chamber, at least one burner lance with a first, a second and third nozzles, first, second and third feed chambers fluidly connected to each of a nozzle for supplying gases into the combustion chamber, the nozzles having one end in the combustion chamber and another end in each case a feed chamber and the combustion chambers in the region of the end of the nozzles have a burner muffle, further developed in that the first supply chamber is designed for supplying an oxygen supplier for the combustion. The second supply chamber is configured to supply the low calorie combustible gas and 0 ₂ depleted gas. The third supply chamber is designed to supply the high-calorie fuel gas. Further, supply means for supplying the low-calorie combustible gas and the O ₂ -depleted gas to the second supply chamber is provided so as to introduce either the low-calorie fuel gas or the 0 ₂ -depleted gas into the second supply chamber depending on the operation mode of the multi-gas burner becomes.

In generic burner lances with at least three nozzles usually in a first operation, a nozzle for the oxygen supplier for the combustion and a second nozzle for the first fuel gas and in a second operation, a third nozzle for the second combustion gas and further the first nozzle for the oxygen supplier for the combustion uses. Taking into account the inventive idea that it is necessary in the combustion of high calorific gases to operate the multi gas burner with increased λ values compared to a low calorie operation, and consequently that to maintain maximum oxygen contents of the heated process gas there is a need to admix O ₂ -abgereichert.es gas of the air, this has been recognized that the second nozzle of a burner lance is not used when high calorific operation in contrast to the low caloric operation and can therefore meet this dual function. This dual function can be seen in the supply of low-calorie fuel gas in low calorie operation and the supply of O ₂ -depleted gas in high-calorie operation.

This results in contrast to the use of four nozzles, each performing only a single function, the advantage that the multi-gas burner according to the invention has a smaller size, space and investment costs - - And he is more flexible. Also can be saved in terms of material and design costs, since a construction of a burner lance with four nozzles is more expensive than the use of a burner lance with three nozzles.

Here, a burner lance with three nozzles having an outer tube, a central tube and an intermediate tube arranged between the outer and the central tube. The tubes are each coaxially aligned with each other and spaced from each other to form annular gaps or flow cross-sections. The burner lance is thus constructed of three coaxially nested tubes, each resulting flow cross-section is connected to a separate feed chamber. The annular gap between the outer and the intermediate tube forms an outer nozzle, the annular gap between the intermediate and the central tube forms a central nozzle and the central tube the inner nozzle.

In one embodiment of the invention, the first nozzle is an outer nozzle, the second nozzle an intermediate nozzle and the third nozzle an inner nozzle of a burner lance. It is further provided that the first nozzle with the first supply chamber, the second nozzle with the second supply chamber and the third nozzle with the third supply chamber are each connected fluidically. This ensures that the air is introduced in the low calorie as well as in the high calorie operation through the outer nozzle. In low calorie operation, the low calorific fuel gas is introduced through the adjacent central nozzle, thus enabling good mixing between the fuel gas and the air, which is the oxygen source for combustion.

Analogously, the air is introduced through the outer nozzle in high-calorie operation and the O ₂ -degraded gas through the middle nozzle, which can premix. The high-calorie fuel gas is introduced through the inner nozzle. As a result, a good mixing of the fuel gas with the oxygen carrier formed from air and 0 ₂ -depleted gas for combustion is possible again.

Furthermore, a control device is provided which is designed to introduce the low-calorie fuel gas into the second supply chamber in a low-calorie operation into the first supply chamber and to block the supply to the third supply chamber. The control device is further configured in this way. - - det, in a high-calorie operation in the first supply chamber air, in the second supply chamber O2-enriched gas and in the third supply chamber to initiate the high-calorie fuel gas. By such a control device is achieved that is not falsely introduced in the low calorie operation in addition to the low calorie fuel gas O2-depleted gas in the second supply chamber. This could lead to an uncontrolled combustion behavior in the combustion chamber.

Preferably, the cross-sectional area of the first to the second nozzle and to the third nozzle has a ratio in the range of 4.4 - 5.0: 5.9 - 6.3: 1, in particular 4.7; 6.2: 1 up. Depending on the gas used, the cross-sectional ratios may also be deviating therefrom and depend essentially on the λ values used, the low-calorie and high-calorie fuel gas, the respective stoichiometric air requirement of the gases and / or the operating or injection pressure. By such a design of the cross-sectional areas, which essentially determines the possible flow of the corresponding gases, it is achieved that sufficient hot gas can be generated with the multigas burner thus formed in both operating modes. In particular, the design of the second nozzle can be decisive for this, since it is for two different gases, once low calorific fuel gas and in the other operating state O2-abgereicht.es gas used.

It is advantageous if a plurality of burner lances are provided and the first nozzle of each burner lance is fluidically connected to the first supply chamber, every second nozzle is fluidically connected to the second supply chamber and every third nozzle is fluidically connected to the third supply chamber. A burner lance is a complete multigas burner in the minimum case. The desired burner output can be achieved by selecting the number of burner lances. The individual burner lance is normalized to a certain power, so that no enlargement of the burner SCALE-UP must be made. This is referred to as a "numbering-up", meaning that it is not necessary to take into account changed criteria with regard to geometry, flow behavior, etc. By using several burner lances in the multi gas burner, a higher overall performance of the multi gas burner can be achieved - - In addition, a better control behavior can be achieved by the use of burner lance. A major reason for this is the "mutual support" of a burner lantern, ie that you can downgrade the power and the variety of burner lances repeatedly serves as a "source of ignition" so that the individual flame does not go out. Thus, control ratios up to 1: 15 are possible even with low calorific gases, although the admission pressure of the components involved in the combustion is in the low pressure range.

The fact that only three supply chambers are provided, the overall construction of the multi-gas burner facilitates.

The invention further relates to a process plant with a multigas burner according to the invention and a grinding plant for solid fuels z. B. a Kohlenmahlanlage. This may in particular be a roller mill, wherein the Kohlenmahlanlage is provided as a means to be used as a source of 02-depleted gas. The O 2 -depleted gas can be recirculated process gas from the milling process, in particular a grinding-drying process. Of course, such a constellation is also applicable to any other thermal process, i. Use of several gases, low 02 contents in the process gas and their use as Rezigas, high control ratios etc ..

By means of a control device, which may also be designed as a control and regulating device, the inflows of the various gases, the high-calorie fuel gas, the low-calorie combustible gas, the air and the 02-depleted gas depending on the operating mode are set accordingly. In this case, the control or regulation takes place in such a way that the necessary calorific value with a flame temperature below 1,300 ° C. and with a maximum oxygen content, in particular below 10%, of the hot process gas is achieved in a high-calorie operation. In an analogous manner, the tributaries are controlled in the low calorie operation by the control and regulating device such that a sufficient calorific value is achieved without reaching a high flame temperature. When using low calorific gases, the low calorific value causes low combustion temperatures, so that there are no significant O 2 problems in the process gas. The respective properties can in particular by - - Setting the amounts of the gases used and the ratio of the gases are set to each other.

The invention will be explained below with reference to exemplary embodiments and schematic drawings. In these drawings show:

1 shows a simplified construction of a multigas burner according to the invention; and

2 shows a process diagram of a coal grinding plant with multigas burner according to the invention.

In Fig. 1, a simplified structure of a multi-gas burner 1 according to the invention is shown. The multigas burner 1 shown here has two burner lances 10 which are each designed as three-lance burners or three-nozzle lances and have a first nozzle 11, a second nozzle 12 and a third nozzle 13. The burner lances 10 each end in a combustion chamber 3.

Furthermore, the multi-gas burner 1 according to the invention has a first supply chamber 21, a second supply chamber 22 and a third supply chamber 23. The nozzles 11, 12, 13 of the burner lance 10 are formed by three coaxially aligned tubes. The first nozzle 11 terminates in the first supply chamber 21. The second nozzle 12 terminates in the second supply chamber 22 and the third nozzle 13 terminates in the third supply chamber 23. Here, the nozzles 11, 12, 13 and the tailpipes respectively with flange-like connections the inner wall of the respective feed chamber 21, 22, 23 be attached. Furthermore, in the middle of the multigas burner 1, a starting burner 7 is provided, which is used to start the multigas burner 1.

Further, a supply 31 to the first supply chamber 21, a supply 32 to the second supply chamber 22 and a supply 33 to the third supply chamber 23 is provided. Furthermore, an additional fourth feed 34 is provided, which likewise ends in the second feed chamber 22. The feeders 31, 32, 33, 34 have valves which can be controlled by a control device 36. - -

The feeder 31 is connected to an air source. This is normal outdoor air. The supply line 32 is connected to a source of low calorific fuel gas. This may be, for example, blast furnace gas. Such low-calorie combustion gases are also referred to as lean gases. The supply line 33 is connected to a source of a high-calorie fuel gas, which may also be referred to as rich gas. The feed line 34 in turn is connected to a source of O ₂ -depleted gas. This may in particular have a 0 ₂ content of less than 10%.

For low calorie operation, the control device 36 controls the valves of the feeders 31, 32, 33 and 34 such that air flows into the first feed chamber 21 via the feed line 31 and into the second feed chamber 22 via the feed 32 a low calorific fuel gas. The other two leads 33 and 34 are closed here. The ratio of air passing through the nozzle 11 into the combustion chamber 3 and the low calorific gas flowing through the nozzle 12 into the combustion chamber 3 is adjusted so that the λ value is in the range of 1.1.

For a highly calorific operation, the control device 36 opens the valves of the feed lines 31, 33 and 34. In this way, air flows into the feed chamber 21, O ₂ -abgereicht.es gas into the feed chamber 22 and high calorific gas in the feed chamber 23. About the nozzles 11, 12, 13, these gases can flow into the combustion chamber 3 and react with each other there.

Here, the controller 36 controls the inflow of the air, the 0 ₂ -depleted gas and the high-calorie combustion gas so that a λ value is set in the range of 1.6, with approximately 30% of the oxygen carrier for the combustion being O ₂ -depleted gas is. At the combustion chamber end of the burner lance 11 may be provided in the region of the respective end of the nozzle swirling means to mix the outflowing gases well together.

As an alternative to the supply 34, other embodiments are possible in which the chamber 22 can be supplied with both the low-calorie fuel gas and the 02-depleted gas. For example, it is conceivable to supply both low-calorie gas and O ₂ -depleted gas via the feed 32. - to be able to lead. This can be made possible by a corresponding supply line and a three-way valve. In this case, the supply line 34 can be dispensed with.

FIG. 2 shows a process diagram of a coal grinding plant with a hot gas generator which uses a multigas burner 10 according to the invention.

A central element of the process engineering plant shown here is, on the one hand, the mill-sifter combination 52, which may be, for example, a vertical roller mill with circulating air operation, in particular a LOESCHE roller mill. On the other hand, a hot gas generator 51 is provided which has a multigas burner 10 according to the invention. The hot gas generator 51 is used to generate hot process gases or their heating, which are used in the milling process in the mill-sifter combination 52 to dry the material to be ground, in this case raw coal, in addition to the grinding process. For this purpose, a hot gas supply 54 is provided between the hot gas generator 51 and the mill-sifter combination 52.

A coal grinding plant is to be seen here merely as an example of a process plant in which a hot gas generator 51 is used. Instead of a mill-sifter combination 52, other parts of the plant can be provided in which generated hot process gas is used.

Via a coal bunker 61, the raw coal to be ground is fed to the mill-classifier combination 52. In the mill-sifter combination 52, the raw coal is ground into dust and, with the aid of the hot gas, which flows via the feed 54 into the mill-sifter combination 52, dried and transported in the direction of a filter 62 by means of air flow.

In the filter 62, the generated carbon dust is separated and fed to a dust bin 63. From the dust bin 63, the carbon dust can then be deducted and its use, for example, for PCI process, fed. The process gas purified from the dust, which in the meantime has also cooled down, is sent to the hot gas generator 51 via a process gas recirculation 56. Here it is heated by the combustion energy and passed back via the hot gas supply 54 to the mill-sifter combination 52. - -

The multi-gas burner 10 of the hot gas generator 51 has four different feeds. Feeder 71 is used to supply a low calorific fuel gas, such as top gas, supply 72 for supplying air, supply 73 for supplying a high-calorie fuel gas, such as coke gas and feed 74 for supplying gas to the starting burner. For this purpose, for example, natural gas can be used.

In order to be able to mix 0 ₂ -depleted gas in the air when firing the multi-gas burner with the high-calorie gas according to the method of the invention, it is further provided to provide a recycle branch 57 in the process gas recirculation 56. This ends at a Rezigaszuführung 76, which ends in the supply line for the low calorie fuel gas.

Thus, it is possible, depending on the selected operating mode of the multi gas burner 10 of the hot gas generator 1, to supply the low calorie fuel gas via the supply 71 or Rezigas as 0 ₂ depleted gas recovered from the recirculated process gas. This recirculated process gas is also referred to as Rezigas.

With the method according to the invention and the multi-gas burner according to the invention, it is thus possible to use both low calorific gases and highly calorific gases in compliance with environmental and safety specifications for the production of hot process gases.

Claims

1. A method for operating a multi gas burner (1) with a low and a high calorie fuel gas, wherein the multi gas burner (1)

 at least one burner lance (10) having a first (11), a second (12) and a third nozzle (13),

 - A first (21), a second (22) and a third feed chamber (23), each with a nozzle (11, 12, 13) are fluidly connected and

 a combustion chamber (3) into which projects the at least one burner lance (10),

 characterized,

that in a high-calorie operation simultaneously via the first nozzle (11) air, via the second nozzle (12) O2-depleted gas and the third nozzle (13) a highly calorificated fuel gas into the combustion chamber (3) are passed and there to the reaction, especially for burning, the air and the 0 ₂ -depleted gas being used as oxygen carriers for the combustion.

2. The method according to claim 1,

 characterized,

that in a low calorie operation simultaneously via the first nozzle (11) air as oxygen carrier for the combustion and the second nozzle (12) a low calorific fuel gas into the combustion chamber (3) are passed and there for reaction, in particular for burning, brought.

3. The method according to claim 1 or 2,

 characterized,

 in that an outer nozzle is selected as the first nozzle (11), an inner nozzle as the second nozzle (12), and an inner nozzle as the third nozzle (13).

4. The method according to any one of claims 1 to 3,

 characterized,

 that the multi-gas burner (1) is operated in low calorie operation with a λ-value in the range of about 1.05 to about 1.2.

5. The method according to any one of claims 1 to 4,

 characterized,

 that the multi-gas burner (1) in high-calorie operation with a λ-value of about 1.4 to about 2.0 is operated, with about 15% to 30% of the oxygen supplier come from the 02-depleted gas.

6. The method according to any one of claims 1 to 5,

 characterized,

that the λ value in low calorie operation and the λ value and the admixture of O ₂ -depleted gas in high-calorie operation are set such that the hot gases have an O ₂ content of less than 10%.

7. The method according to any one of claims 1 to 6,

 characterized,

 that the amount of the fuel gas, the λ value and the composition of the oxygen carrier for the combustion of air and O2-depleted gas is adjusted so that a flame temperature of 1300 ° C is not exceeded.

8. The method according to any one of claims 1 to 7,

 characterized,

in that a recirculated process gas from a grinding operation, in particular a solid fuel grinding plant, is used as O 2 -depleted gas.

9. The method according to any one of claims 1 to 8,

 characterized ,

 that coke oven gas is used as the high calorific gas and blast furnace gas is used as the low calorific gas.

10. Multi gas burner (1) for operation with a low and a high calorific fuel gas with

 a combustion chamber (3),

 at least one burner lance (10), having a first (11), a second (12) and a third nozzle (13),

 a first (21), second (22) and third supply chamber (23), which are fluidically connected for feeding gases into the combustion chamber, each with a nozzle (11, 12, 13),

 - wherein the nozzles (11, 12, 13) terminate with one end in the combustion chamber (3) and with another end in a respective feed chamber (21, 22, 23),

 - wherein the combustion chamber (3) in the region of the end of the nozzles (21, 22, 23) has a burner muffle,

 characterized ,

 in that the first supply chamber (21) is designed to supply an oxygen carrier for the combustion,

 in that the second supply chamber (22) is designed to supply the low-calorie combustible gas and O 2 -depleted gas,

 the third supply chamber (23) is designed to supply the high-calorie fuel gas,

in that a supply device is provided for feeding the low-calorie combustible gas and the 0 ₂ -depleted gas into the second supply chamber (22) which is designed either for the low-calorie fuel gas or the 0 ₂ -depleted gas, depending on the operating mode of the multigas burner (1) to introduce into the second feed chamber (22).

11. Multi gas burner (1) according to claim 10

 characterized,

 in that the first nozzle (11) is an outermost nozzle, the second nozzle (12) is a central nozzle and the third nozzle (13) is an inner nozzle of the burner lance (10), the first nozzle (11) being connected to the first supply chamber (21 ) is fluidically connected,

 the second nozzle (12) is fluidically connected to the second supply chamber (22) and

 in that the third nozzle (13) is fluidically connected to the third supply chamber (23).

12. Multi gas burner (1) according to claim 10 or 11,

 characterized,

 a control device is provided which is designed in a low calorie mode into the first supply chamber (21) for air, to introduce the low calorie fuel gas into the second supply chamber (22) and to block the supply to the third supply chamber (23),

 and in that the control device is designed to introduce air in a high-calorie mode into the first feed chamber (21), gas 02-depleted gas into the second feed chamber (22) and the high-calorie fuel gas into the third feed chamber (23).

13. Multi gas burner (1) according to one of claims 10 to 12,

 characterized,

 a ratio of the cross-sectional areas of the first (11) to the second (12) to the third nozzle (13) is dependent on the λ values used, the low-caloric and high-calorie fuel gas and / or the respective stoichiometric air requirement, and in particular in the Range of about 4.5 - 4.9: 6.0 - 6.4: 1.

14. Multi gas burner (1) according to one of claims 1 to 13,

 characterized,

in that a plurality of burner lances (10) are provided and in that each first nozzle (11) is fluidically connected to the first supply chamber (21), every second one Nozzle (12) with the second supply chamber (22) and each third nozzle (13) with the third supply chamber (23) is fluidly connected.

15. Process engineering plant

with a ultigasbrenner (1) according to any one of claims 10 to 14 and with a thermal process being used as 0 ₂ -depleted gas recirculated process gas from the thermal process is used.