EP3650757A1 - Gas turbine and method for operating the same - Google Patents

Abstract

The invention relates to a gas turbine which comprises at least one first burner for a first fuel gas and at least one second burner for a second fuel gas. The structure of the first burner and the second burner are different. The first burner can be operated with a conventional fuel gas. Natural gas in particular is considered here as a conventional fuel gas. The second burner can be operated with hydrogen. The gas turbine, which comprises a first and a second burner, is operated such that the first burner is operated with a first fuel and the second burner with a second fuel, the second fuel being hydrogen.

Description

The invention relates to a gas turbine and a method for operating a gas turbine.

The availability of fossil fuels, especially natural gas, as fuel for gas turbines is limited. At the same time, valuable resources are generated as part of the development of renewable energy sources in times with a lot of sun and a lot of wind, i.e. with above-average solar power or wind power generation. This valuable substance can in particular be hydrogen, which is generated with water electrolysers. Hydrogen is already used as a fuel in modern gas turbines.

So far, burner systems have been used for a high fuel flexibility of the gas turbines, which can offer a wide range of fuels from natural gas to hydrogen-rich synthesis gases or alternative fuels. In these burner systems, the hydrogen content may typically not exceed 60%. With higher hydrogen contents, the nitrogen oxide values rise sharply and the reaction and thus the flame speed of the fuel gas mixture increases. In order to protect the burner hardware, the flame speed must not exceed a certain value in order to avoid the risk of a flashback into the burner, which would be destroyed in the process.

Another difficulty of the burner systems for fuel mixtures is that the combustion properties of the hydrogen-natural gas mixture differ from the combustion properties of the pure natural gas. The proportion of hydrogen in the hydrogen-natural gas mixture also influences the combustion properties. In particular, the shape and behavior of the flame changes within the combustion chamber. This can disadvantageously damage the burner and the combustion chamber.

The object of the invention is therefore to provide a gas turbine with a burner system and a method for operating the gas turbine which can be operated flexibly in different proportions with hydrogen and conventional fuels and overcomes the problems mentioned.

The object is achieved with a gas turbine according to claim 1 and a method for operating a gas turbine according to claim 6.

A gas turbine according to the invention comprises at least a first burner for a first fuel gas and at least a second burner for a second fuel gas. The structure of the first burner and the second burner are different. The first burner can be operated with a conventional fuel gas. Natural gas in particular is considered here as a conventional fuel gas. The second burner can be operated with hydrogen.

In other words, this means that the second burner can be operated with pure hydrogen or with a hydrogen mixture, wherein the mixture can also comprise nitrogen, carbon dioxide and / or water in addition to the hydrogen.

According to the invention, the gas turbine, which comprises a first and a second burner, is operated such that the first burner is operated with a first fuel and the second burner with a second fuel, the second fuel being hydrogen.

Both the first and the second fuel can represent pure components or mixtures of substances.

It is advantageously possible to use the burners individually by using at least two different burner structures adapt to the properties of the fuel used. The flashback of flames is advantageously avoided by the second burner adapted to the hydrogen. Furthermore, the nitrogen oxide emissions are lower due to the adapted burner.

Furthermore, in the sense of the invention it is also possible to arrange more than two different burners in the gas turbine. In this way, new fuels or fuel mixtures can be burned in a third burner in the gas turbine. The gas turbine can therefore be individually adapted to new fuels without having to change the entire layout of the gas turbine. Advantageously, only a burner adapted to the new fuel is necessary.

In an advantageous embodiment and development of the invention, the second burner is a pore burner. Pore burners use microporous structures through which the fuel gas flows, exits finely divided and then mixes and reacts with air. Combustion air and fuel are fed separately, so that advantageously no flashback is possible.

In a further alternative embodiment, the second burner can be an arrangement of macroscopic small burners, similar to micromixing chamber burners or matrix burners. These burners produce a lot of small flames. The combustion can take place without gas premixing. Few nitrogen oxides are therefore advantageously produced. Another advantage is that these small burners are safe against flashback.

In a further alternative embodiment, the second burner can comprise an arrangement of catalytically active material. With this type of burner, there is a surface reaction between the fuel and the atmospheric oxygen. Few to no nitrogen oxides are therefore advantageously produced. Advantageous is that this type of burner is safe against flashback.

In a further alternative embodiment and development of the invention, the second burner can be a DOC burner. These burners are characterized by flameless combustion. The combustion takes place in a volume reaction. Few nitrogen oxides are therefore advantageously produced. It is also advantageous that these burners are safe against flashback.

All these types of burners can advantageously be designed such that they are used in a conventional gas turbine. It is also possible to use at least three different types of burners in a gas turbine.

In a further advantageous refinement and development of the invention, the total number of first and second burners is in a range between 5 and 50. In principle, the number of burners is predetermined depending on the gas turbine type. The more burners, the fewer the steps of the possible mixing ratios between the first fuel and the second fuel.

In a further embodiment and development of the invention, the first and / or second burner are interchangeable. It is advantageously possible to adapt the gas turbine to new fuels or fuel mixtures with very little adjustments to the gas turbine itself.

In a further advantageous embodiment and development of the invention, the gas turbine comprises a control system which sets a first amount of fuel gas for the first burner and / or a second amount of fuel gas for the second burner. The gas turbine can then react advantageously to small fluctuations by means of the control system and adapt the amount of fuel gas accordingly.

In a further advantageous embodiment and development of the invention, the hydrogen is produced in a water electrolyser by means of electrolysis. It can be a chlor-alkali electrolysis or an electrolysis with a proton exchange membrane (PEM electrolysis). In times of high sun and / or wind, electrical energy can advantageously be stored by splitting water into hydrogen and oxygen. The hydrogen can then be stored and, in times with little sun and / or wind, converted into mechanical energy by means of the gas turbine.

In a further advantageous embodiment and development of the invention, the first and the second burner can be operated with essentially the same pressure loss. This advantageously makes it possible to replace the burners and to make few or no changes to the operating parameters of the gas turbine, in particular the fuel throughput.

Further features, properties and advantages of the present invention will become apparent from the following description with reference to the accompanying figure. The figure shows schematically a gas turbine with a first and a second burner.

The gas turbine 1 comprises a compressor 4, a plurality of first burners 2 and a second burner 3. It also comprises a turbine 5. The gas turbine 1 comprises an air inlet 6, through which air can be fed in for the first burners 2. The gas turbine 1 also includes a hydrogen inlet 7, into which hydrogen can be fed for the second burner 3.

The gas turbine further comprises connecting flanges 10, which firmly connect the burners to the turbine 5. The first burner 2 and the second burner 3 can both be connected to the connecting flanges 10. In other words, both are the first burner 2 and also the second burner 3 are compatible with the gas turbine and can be connected to the gas turbine without structural changes. The first burners 2 and second burners 3 can thus advantageously be replaced as required, in particular in the case of modernization measures.

The second burner 3 is in particular an arrangement of macroscopic small burners. Such a burner creates many small flames. The combustion can take place without gas premixing. Few nitrogen oxides are therefore advantageously produced. Another advantage is that the burner is safe against flashback.

In this example, the gas turbine 1 is configured as a tube-ring combustor. Alternatively, however, it is also possible to design the gas turbine with an annular combustor.

Reference symbol list

1

Gas turbine

2nd

first burner

3rd

second burner

4th

compressor

5

turbine

6

Air intake

7

Hydrogen inlet

10th

Connecting flange

Claims (12)

Gas turbine (1) comprising at least one first burner (2) for a first fuel gas and at least one second burner (3) for a second fuel gas, the first burner (2) and the second burner (3) being different in structure, the first Burner (2) can be operated with a conventional fuel gas and the second burner (3) can be operated with hydrogen. Gas turbine (1) according to claim 1, wherein the second burner (3) is a pore burner. Gas turbine (1) according to claim 1, wherein the second burner (3) represents an arrangement of macroscopic miniature burners. The gas turbine (1) according to claim 1, wherein the second burner is a catalytic burner. The gas turbine (1) according to claim 1, wherein the second burner is a DOC burner. Gas turbine (1) according to one of claims 1 to 5, wherein a total number of the first (2) and second burners (3) is in a range between 5 to 50. Gas turbine (1) according to one of claims 1 to 6, wherein the first (2) and / or second (3) burner is interchangeable. Method for operating a gas turbine (1), the gas turbine (1) comprising at least a first (2) and at least a second burner (3), the first burner (2) being operated with a first fuel gas and the second burner (3 ) is operated with hydrogen as the second fuel gas. A method according to claim 8, wherein the gas turbine (1) comprises a control system which a first amount of fuel gas for sets the first burner (2) and / or a second quantity of fuel gas for the second burner (3). Method according to one of claims 8 or 9, wherein the hydrogen is produced in a water electrolyser by means of electrolysis of water. Method according to one of claims 8 to 10, wherein the first (2) and the second burner (2) is operated with a substantially equal pressure loss. Method according to one of claims 8 to 11, wherein the second burner is operated with pure hydrogen or with a mixture comprising hydrogen.

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