WO2020082100A1 - Fuel cell system and method for operating same - Google Patents

Abstract

The present invention relates to a fuel cell system (1a; 1b; 1c; 1d), comprising at least one fuel cell stack (2) having an anode portion (3) and a cathode portion (4), an afterburner (5) for at least partial combustion of anode waste gas from the anode portion (3), the afterburner (5) having a gas combustion chamber (7) for the combustion of anode waste gas resulting in flame formation. The invention also relates to a method for operating a fuel cell system (1a; 1b; 1c; 1d) according to the invention. In addition, the invention relates to the use of a fuel cell system (1a; 1b; 1c; 1d) according to the invention for providing electrical energy in a stationary power plant.

Description

 Fuel cell system and method for operating the same

The present invention relates to a fuel cell system, in particular an SOFC system, comprising at least one fuel cell stack with an anode section and a cathode section, an afterburner for at least partial combustion of anode exhaust gas from the anode section and / or cathode exhaust gas from the cathode section. In addition, the invention relates to a method for operating a generic fuel cell system and the use for a generic fuel cell system.

In SOFC systems, catalytic afterburner or

Anode off-gas burners are used to burn anode off-gas from an anode portion of a fuel cell stack. The anode exhaust gas usually still contains the fuel gases directly downstream of the fuel cell stack

Hydrogen and carbon monoxide with typical volumetric proportions of 8-10% hydrogen and 4-5% carbon monoxide. In conventional systems, the anode exhaust gas is burned catalytically with the cathode exhaust air. If you mix both gas streams, there are very high air ratios or a corresponding one

Combustion air ratio. This means that there is usually significantly more oxygen available for combustion in the afterburner than is necessary. At the same time, the combustion temperature is thereby reduced, as a result of which the operating temperature in such an afterburner can be reduced. Due to the coating, catalytic afterburner have certain temperature limits that must not be exceeded, since otherwise the coating could be permanently damaged. If this catalytic afterburner is also used as a starting burner for the heating process, it must also be possible to burn another gas, such as natural gas. In such a case, a relatively high outlay for the catalytic coating of the afterburner must be carried out. There are also special deviations from normal operation. For example, in the event of load shedding of the SOFC system, it can happen that the fuel gas in the fuel cell stack can no longer be converted electrochemically and thus arrives completely in the afterburner. At the present temperatures, however, it can now become a

complete combustion and a significantly higher thermal load for the catalyst than in normal operation. This can lead to permanent damage to the catalytic afterburner and the desired one Lifetime can no longer be achieved, which means before reaching the

exhaust gas emissions to be avoided can result in maximum service life of the afterburner.

As an alternative to catalytic afterburners, afterburners are also occasionally used in SOFC systems to burn anode exhaust gas with the formation of flames. Such a system can be the international patent application

WO 2016/087389 A1. An SOFC system with an afterburner is described there, the afterburner for the oxidation of

Anode exhaust gas is configured by flame combustion. Only fresh air is used to burn the anode exhaust gas. The

The combustion temperature is set up to 1480 ° C to ensure that all carbon monoxide components are burned in the afterburner. However, this has the consequence that nitrogen oxides to be avoided during combustion can be formed.

The object of the present invention is that described above

To take account of the problem at least in part. In particular, it is an object of the present invention to provide a fuel cell system with an improved exhaust gas aftertreatment. It is also the task of the present

Invention to provide a method for operating such a fuel cell system.

The above object is solved by the claims. In particular, the above object is achieved by the fuel cell system according to claim 1, the method according to claim 14 and the use of a

Fuel cell system according to claim 19 solved. Further advantages of the invention result from the subclaims, the description and the drawings. Features and details apply in connection with the

Fuel cell system are described, of course also in

Connection with the inventive method for producing the

Fuel cell system and vice versa, so that with respect to the disclosure of the individual aspects of the invention, reference can always be made to one another. According to a first aspect of the present invention, a

Fuel cell system, in particular a stationary SOFC system, provided. The fuel cell system has at least one fuel cell stack with an anode section and a cathode section, an afterburner for at least partially burning anode exhaust gas from the anode section. The afterburner has a gas combustion chamber for burning anode exhaust gas with the formation of flames.

According to the invention, the afterburner is configured without a catalyst. The afterburner is therefore designed in the form of a gas burner. In order to realize the combustion and to achieve a desired combustion air ratio in which flame combustion is possible, only a definable part of the cathode exhaust gas can be mixed with the anode exhaust gas as combustion air. About the amount of cathode exhaust can easily

Flame temperature can be controlled. If the afterburner is not designed catalytically, other materials for the afterburner or the

Select the gas combustion chamber that is more temperature stable. Above all, short, strong temperature increases mean that there are no longer any problems. A possibly excess portion of the cathode exhaust gas can be mixed into the afterburner exhaust gas downstream of the afterburner.

Experiments within the scope of the invention have shown that the high process temperature of, for example, over 800 ° C. enables a gas burner to be oxidized as desired. This also favors the combustion of carbon monoxide. With the right one

Combustion air ratio, which is set, for example, to a value between 1 and 1, 4, in particular to about 1, 2, it is possible to oxidize the anode exhaust gases.

It may be favorable if an exhaust gas catalytic converter is provided for the catalytic treatment of afterburner exhaust gas, the exhaust gas catalytic converter being arranged at a distance downstream from the afterburner.

In the event that complete combustion of carbon monoxide is not possible at certain operating points, the exhaust gas catalytic converter, which is designed in particular for carbon monoxide, is further in the fuel cell system according to the invention arranged downstream of the afterburner. The catalytic converter can

Compared to conventional SOFC systems with catalytic afterburner can be designed significantly smaller, since only small amounts of carbon monoxide are generated.

It is also an advantage that the ignition should be burned under

Flame formation is much easier than catalytic combustion can be detected. While combustion takes place without a flame in catalytic afterburners, a wide variety of ignition detection options can be implemented for a gas burner.

The exhaust gas catalytic converter, which is connected to the afterburner, enables better emission values to be achieved. The exhaust gas catalyst is relieved by the afterburner. This also reduces the probability of failure of the

Exhaust gas catalyst reduced and the achievement of desired emission targets can be improved over the lifetime of the fuel cell system.

In conventional fuel cell systems, it is known to position an exhaust gas catalytic converter downstream of the afterburner. This is the

Exhaust gas catalyst spaced downstream, in particular separately from

Afterburner arranged. More specifically, the afterburner has a first one

Housing and the catalytic converter has a second housing or is configured in a second housing, the second housing being arranged downstream from the first housing, in particular in the form of a separate housing separate from the afterburner or from the first housing. As a result, the catalytic converter can be designed for particularly low temperatures. A disadvantage of an exhaust gas catalytic converter connected directly after the afterburner is that it can become too hot for a short time during operation and be damaged as a result.

In a particularly advantageous embodiment variant, the

Exhaust catalytic converter can be completely dispensed with.

The afterburner is preferably designed as a self-igniting afterburner. This means that there is no need for a separate ignition device. The

Fuel cell system is preferred as SOFC system, in particular as

stationary SOFC system, designed. The fuel cell system can or have several fuel cell stacks. The anode exhaust gas can be understood to mean anode supply gas processed in the at least one fuel cell stack, in particular processed hydrogen, which is output from the anode section. The cathode exhaust gas can be understood to mean cathode supply gas processed in the at least one fuel cell stack, in particular an oxygen-containing fluid, preferably air, which is output from the cathode section. The afterburner is particularly preferably designed as a flame burner.

It is beneficial if upstream of the afterburner

 Cathode exhaust branch with a first cathode exhaust branch to the afterburner and a second cathode exhaust branch to a first mixing chamber. This makes it possible to divide the cathode exhaust gas downstream of the fuel cell stack in such a way that an optimized stoichiometry is achieved in the afterburner. As a result, a flame temperature in the afterburner can subsequently be regulated, in particular without an oxidizing agent having to be supplied externally. In the optimal case, an exhaust gas catalytic converter can thus be dispensed with entirely. The cathode exhaust gas is divided in particular in such a way that there is a combustion ratio between l = 1.5 and l = 2 in the afterburner. Without a division of the cathode exhaust gas, the combustion ratio in the afterburner is between l = 4 and l = 10.

According to a further aspect of the present invention, it is possible that in a fuel cell system downstream of the afterburner, a hot side of a cathode gas heat exchanger of the fuel cell system is configured and the exhaust gas catalytic converter downstream of the hot side of the

Cathode gas heat exchanger is arranged. In an area downstream of the cathode heat exchanger, the operating temperatures in the exhaust gas catalytic converter can be between 250 ° C and 400 ° C. The catalytic coating of the

The exhaust gas catalytic converter is no longer endangered by thermal stress. In addition, exhaust emission targets can be reliably achieved over the entire lifespan of the fuel cell system. The heat generated in the catalytic converter can also be used for heat recovery. As a result, the fuel cell system can be operated particularly efficiently. In addition to the hot side, the cathode gas heat exchanger also has a cold side through which cathode gas, preferably in the form of air, can be supplied to the cathode section. During operation of the fuel cell system, the hot side of the cathode gas heat exchanger is usually hotter than the cold side of the

Cathode gas heat exchanger.

Furthermore, in a fuel cell system of the present invention, it is possible that a hot side of a downstream of the afterburner

Reformer heat exchanger of the fuel cell system is configured and the exhaust gas catalyst is arranged downstream of the hot side of the reformer heat exchanger. Are in the exhaust gas flow direction between the

Afterburner and the catalytic converter further components, such as the cathode gas heat exchanger and / or the reformer heat exchanger, they can serve as thermal buffers in which short-term temperature peaks for components located downstream of the afterburner can be smoothed. A reformer of the fuel cell system can be heated by the reformer heat exchanger. The reformer is designed to convert fuel to hydrogen, which can be fed to the anode section for power generation. In addition to the hot side, the reformer heat exchanger also has a cold side, through which anode gas, preferably in the form of reformed fuel, in particular hydrogen, can be fed to the anode section. During the operation of the fuel cell system, the hot side of the

Reformer heat exchangers are usually hotter than the cold side of the

Reformer heat exchanger.

In a further embodiment variant of the present invention, it is possible that downstream of the afterburner, an afterburner exhaust gas branching section for branching afterburner exhaust gas is designed on a hot side of a cathode gas heat exchanger of the fuel cell system and / or on a hot side of a reformer heat exchanger of the fuel cell system, the exhaust gas catalytic converter being the downstream one hot side of the cathode heat exchanger and downstream of the hot side of the reformer. By branching the afterburner exhaust gas to the two heat exchangers, the temperature of the afterburner exhaust gas can be compared to the use of only one heat exchanger particularly effectively to a desired temperature or to a temperature in a desired temperature range be reduced. The afterburner exhaust branch section may be one

Valve control for branching the afterburner exhaust gas in the direction of the

Have cathode gas heat exchanger and / or in the direction of the reformer heat exchanger. In other words, the branching section is designed to selectively branch off the afterburner exhaust gas in the direction of the cathode gas heat exchanger and / or in the direction of the reformer heat exchanger, in particular depending on an afterburner exhaust gas requirement on the respective heat exchanger.

In a fuel cell system according to the invention, it can also be advantageous if downstream of the afterburner and upstream of the

Afterburner exhaust branching section a first mixing chamber for

Mixing of the afterburner exhaust gas with pure or substantially pure cathode exhaust gas is arranged. The cathode exhaust gas not used in the afterburner can thus still be used downstream of the afterburner, for example to heat cathode supply gas to the cathode section through the cathode gas heat exchanger and / or anode supply gas to the anode section through the reformer heat exchanger. By means of the first mixing chamber, the efficiency of the mode of operation of the

Fuel cell system to be improved. In order to lead cathode exhaust gas directly to the first mixing chamber, there is an upstream of the afterburner

Cathode exhaust branch section with a first cathode exhaust branch to the afterburner and a second cathode exhaust branch to the first mixing chamber. The cathode exhaust branch portion may be in the form of a

Valve control can be designed or have a suitable valve control.

Furthermore, in a fuel cell system according to the present invention, it is possible that downstream of the hot side of the

Cathode heat exchanger, downstream of the hot side of the

Reformer heat exchanger and upstream of the catalytic converter, a second mixing chamber for mixing the afterburner exhaust gas downstream of the hot side of the cathode heat exchanger and the afterburner exhaust gas is arranged downstream of the hot side of the reformer heat exchanger. By mixing the afterburner exhaust downstream of the hot side of the

A cathode heat exchanger and the afterburner exhaust gas downstream of the hot side of the reformer heat exchanger upstream of the catalytic converter can Particularly uniform catalytic combustion of the afterburner exhaust gas can be achieved. The second mixing chamber is preferably arranged upstream of the exhaust gas catalytic converter directly on the exhaust gas catalytic converter. The exhaust gas catalytic converter preferably has an exhaust gas catalytic converter housing, in particular in the form of the second housing described above, in which the second

Mixing chamber is designed or which, among other things. forms the second mixing chamber.

In addition, in a fuel cell system according to the invention it can be advantageous if an ignition detection unit for detecting an ignition and / or a combustion with flame formation in the gas combustion chamber is at least partially provided on the afterburner. The

Ignition detection unit can be implemented particularly easily in the afterburner according to the invention in the form of a gas burner. The

According to one embodiment variant, the ignition detection unit can be provided at least partially on the afterburner for acoustic detection of the ignition. Furthermore, it is conceivable that the ignition detection unit has a measuring device for measuring an electrical conductivity of gas in and / or on the combustion chamber and a determination unit for determining the ignition on the basis of the measured electrical conductivity of the gas in and / or on the combustion chamber. It is also possible that the

Ignition detection unit a measuring device for measuring a

Temperature rise of gas in the combustion chamber and a determination unit for determining the ignition based on the measured temperature rise of the gas in the combustion chamber.

According to a further embodiment of the present invention, in the case of a fuel cell system, the at least one fuel cell stack, the afterburner and the exhaust gas catalytic converter can be arranged in a hot box of the fuel cell system, an oxygen supply section for supplying oxygen or an oxygen-containing fluid into the gas combustion chamber being at least partially configured outside the hot box . Outside the hot box, the

Oxygen supply section can be provided with relatively inexpensive materials. In addition, the oxygen supply section is easily accessible in the event of a fault and / or in the event of maintenance. By supplying hot air from outside the hotbox, for example, the afterburner can be easily are heated so that self-ignition can take place when fuel is supplied, in particular in the form of anode exhaust gas. Under a hot box, a housing known in the prior art or a housing-like jacket for shielding high temperatures within the hot box from the rest of the

Fuel cell system can be understood.

In a fuel cell system according to the present invention, it is also possible that at least one in the oxygen supply section

Temperature control for adjustable temperature control of the oxygen or

oxygen-containing fluid is arranged. By arranging the temperature control in the oxygen supply section outside the hot box, the temperature control can be made available inexpensively and with a reliable mode of operation. The temperature control means is designed in particular as a heating means, for example in the form of an electrical heating means. The oxygen supply section preferably branches from a cathode supply gas section for supplying

Cathode supply gas, in particular from air, to the cathode section in the direction of the afterburner. For controlling and / or regulating the oxygen-containing fluid, in particular in the form of air, for the afterburner, there is a valve in the oxygen supply section, preferably upstream of the temperature control means, in particular an on / off valve, for blocking and / or releasing the oxygen supply section, or a adjustable valve designed.

A setting unit of a fuel cell system according to the invention can be configured to set a combustion temperature in the gas combustion chamber to a maximum of 1200 ° C. The fact that the combustion temperature in the

Afterburner or in the gas combustion chamber is kept below 1200 ° C, nitrogen oxide formation can be avoided. The lower combustion temperature accepts that part of a carbon monoxide gas may not be burned. However, this portion can be oxidized in the downstream catalytic converter.

It can be of advantage if a device according to the invention is used

Fuel cell system an adjustment unit for adjusting an

Anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber is configured in a range between 3: 1 and 1: 1, in particular to approximately 2: 1. In extensive tests within the scope of the present invention, in particular through simulation results from a combustion temperature, surprisingly found that the best results for the desired combustion in the afterburner can be achieved with this mixture ratio.

According to a further aspect of the present invention, a method for operating a fuel cell system as described in detail above is proposed. In the method, anode exhaust gas is burned in the afterburner gas combustion chamber with the formation of flames.

It is beneficial if afterburner exhaust gas from the gas combustion chamber

downstream separately and spaced from the afterburner by the

Exhaust gas catalyst is treated catalytically. It is advantageous if cathode exhaust gas is divided upstream of the afterburner via a cathode exhaust branch section, a first part being conducted to the afterburner via a first cathode exhaust branch and a second part being directed to a first mixing chamber via a second cathode exhaust branch.

In a further development of the method according to the invention, it is possible for the combustion temperature in the gas combustion chamber to be set to a maximum of 1200 ° C. by the setting unit. It may also be advantageous if that

Anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber through the

Setting unit, as already described above, is set in a range between 3: 1 and 1: 1, in particular to approximately 2: 1. It brings in

The method according to the invention has the same advantages as have been described in detail with reference to the fuel cell system according to the invention.

Another aspect of the present invention relates to the use of a fuel cell system as described above for providing electrical energy in a stationary power plant. Further measures improving the invention result from the

following description of various embodiments of the

Invention, which are shown schematically in the figures. All features and / or advantages arising from the claims, the description or the figures, including structural details and spatial arrangements can be essential to the invention both individually and in the various combinations.

Each shows schematically:

Figure 1 is a block diagram of a fuel cell system according to a first

 Embodiment of the present invention

Figure 2 is a block diagram of a fuel cell system according to a second

 Embodiment of the present invention

Figure 3 is a block diagram of a fuel cell system according to a third

 Embodiment of the present invention, Figure 4 is a block diagram of a fuel cell system according to a fourth

 Embodiment of the present invention, and

FIG. 5 shows a flow chart for explaining a method according to a

 embodiment according to the invention.

Elements with the same function and mode of operation are given the same reference numerals in FIGS. 1 to 5.

1 shows a block diagram for describing a fuel cell system 1 a according to a first embodiment. The one shown in Fig. 1

Fuel cell system 1 a has a fuel cell stack 2 with one

Anode section 3 and a cathode section 4. The fuel cell system 1 a also has an afterburner 5 for at least partially burning

Anode exhaust gas from the anode section 3 and an exhaust gas catalytic converter 6

downstream of the afterburner for the catalytic treatment of

Afterburner exhaust. The afterburner 5 has a gas combustion chamber 7 for burning anode exhaust gas with the formation of flames. That is, the afterburner 5 is designed in the form of a gas burner. The exhaust gas catalytic converter 6 is arranged downstream from the afterburner 5, but does not necessarily have to be provided.

More specifically, downstream of the afterburner 5 is an afterburner exhaust branch section 20 for branching afterburner exhaust gas to a hot one Side of a cathode gas heat exchanger 8 of the fuel cell system 1 a and on a hot side of a reformer heat exchanger 10 of the fuel cell system 1 a, the exhaust gas catalytic converter 6 downstream of the hot side of the cathode heat exchanger 8 and downstream of the hot side of the

Reformer heat exchanger 10 is arranged.

A first mixing chamber 11 for mixing the afterburner exhaust gas with pure or essentially pure cathode exhaust gas is arranged downstream of the afterburner 5 and upstream of the afterburner exhaust branching section 20. In order to lead cathode exhaust gas directly to the first mixing chamber 11, a cathode exhaust gas branching section 17 is configured upstream of the afterburner 5 with a first cathode exhaust gas branch 18 to the afterburner 5 and a second cathode exhaust gas branch 19 to the first mixing chamber 11.

Downstream of the hot side of the cathode heat exchanger 8, downstream of the hot side of the reformer heat exchanger 10 and upstream of the

Exhaust gas catalytic converter 6 is a second mixing chamber 12 for mixing the

Afterburner exhaust gas downstream of the hot side of the cathode heat exchanger 8 and the afterburner exhaust gas downstream of the hot side of the

Reformer heat exchanger 10 arranged. Basically, the second

Mixing chamber 12 can be dispensed with by the afterburner exhaust gas downstream of the hot side of the cathode heat exchanger 8 and the afterburner exhaust gas

is inserted or applied downstream of the hot side of the reformer heat exchanger 10 directly into the exhaust gas catalytic converter 6 or onto a catalytic coating in a suitable housing.

An ignition detection unit 13 is at least partially configured on the afterburner 5 for detecting ignition and / or combustion with the formation of flames in the gas combustion chamber 7. The fuel cell stack 2, the afterburner 5 and the exhaust gas catalytic converter 6 are arranged in a hot box 14 of the fuel cell system 1 a, an oxygen supply section 15 for supplying an oxygen-containing fluid, in the present case air, into the gas combustion chamber 7 outside or essentially outside the hot box 14 is. in the

Oxygen supply section 15 is a temperature control means 16 in the form of a heating means for adjustable heating of the supply air to the afterburner 5. An adjustment unit 9, which can be designed, for example, in the form of a control device or can have such a control device, is for setting a combustion temperature in the gas combustion chamber 7 to a maximum of 1200 ° C.

configured. For this purpose, the setting unit can have mechanical, electrical and / or digital signal transmitters. The setting unit 9 is further configured to set an anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber 7 in a range between 3: 1 and 1: 1, in particular to approximately 2: 1.

2 shows a fuel cell system 1 b according to a second embodiment. The fuel cell system 1 b shown essentially corresponds to the fuel cell system 1 a shown in FIG. 1. However, it will

Afterburner exhaust gas downstream of the afterburner 5 only through the

Cathode gas heat exchanger 8 passed. This allows the air to

Cathode section 4 or in the cathode gas heat exchanger 8 are heated.

FIG. 3 shows a fuel cell system 1 c according to a third embodiment. The fuel cell system 1 c shown essentially corresponds to the fuel cell system 1 a shown in FIG. 1. However, it will

Afterburner exhaust gas downstream of the afterburner 5 only through the

Reformer heat exchanger 10 passed. As a result, the fuel or the fuel mixture can be specifically heated to the anode section 3 or in the reformer heat exchanger 10.

4 shows a fuel cell system 1 d according to a fourth embodiment. The fuel cell system 1 d shown essentially corresponds to the fuel cell system 1 a shown in FIG. 1. However, the oxygen supply section 15 is dispensed with. This can be compensated for by an electric heating means (not shown) directly on the afterburner 5 and / or by an increased supply of cathode exhaust gas to the afterburner 5.

A method for operating the fuel cell system 1 a shown there according to the first embodiment is explained below with reference to FIG. 1. The method is characterized in that anode exhaust gas is burned in the gas combustion chamber 7 of the afterburner 5 with the formation of flames, and afterburner exhaust gas from the gas combustion chamber 7 downstream separately and at a distance from the afterburner 5 by the exhaust gas catalytic converter 6 is treated catalytically. Here, the combustion temperature in the gas combustion chamber 7 is set by the setting unit 9 such that a maximum value of 1200 ° C. is not exceeded. The

 Anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber 7 is set to approximately 2: 1 by the setting unit 9.

In addition to the illustrated embodiments, the invention leaves further

Design principles too. That is, the invention is not to be considered limited to the exemplary embodiments explained with reference to the figures.

Reference list

1 a fuel cell system

 1 b fuel cell system

 1 c fuel cell system

 1 d fuel cell system

 2 fuel cell stacks

 3 anode section

 4 cathode section

 5 afterburner

 6 catalytic converter

 7 gas combustion chamber

 8 cathode gas heat exchangers

 9 adjustment unit

 10 reformer heat exchangers

 11 first mixing chamber

 12 second mixing chamber

 13 Ignition detection unit

 14 Hotbox

 15 oxygen supply section

 16 tempering agents

 17 cathode exhaust branch section

18 first cathode exhaust branch

 19 second cathode exhaust branch

 20 afterburner exhaust branching section

Claims

Claims

1. Fuel cell system (1 a; 1 b; 1 c; 1 d), having at least one

 Fuel cell stack (2) with an anode section (3) and one

 Cathode section (4), an afterburner (5) for at least partially burning anode exhaust gas from the anode section (3),

 characterized in that

 the afterburner (5) has a gas combustion chamber (7) for burning anode exhaust gas with the formation of flames.

2. fuel cell system (1 a; 1 b; 1 d) according to claim 1,

 characterized in that

 an exhaust gas catalytic converter (6) is provided for the catalytic treatment of afterburner exhaust gas, the exhaust gas catalytic converter (6) being arranged downstream from the afterburner (5).

3. fuel cell system (1 a; 1 b; 1 d) according to claim 1 or 2,

 characterized in that

 a cathode exhaust branch (17) with a first cathode exhaust branch (18) to the afterburner (5) and a second cathode exhaust branch (19) to a first mixing chamber (11) is configured upstream of the afterburner (5).

4. fuel cell system (1a; 1 b; 1 d) according to one of claims 1 to 3,

 characterized in that

 downstream of the afterburner (5) a hot side of a

 Cathode gas heat exchanger (8) of the fuel cell system (1 a; 1 b; 1 d) is configured and the exhaust gas catalytic converter (6) is arranged downstream of the hot side of the cathode gas heat exchanger (8).

5. Fuel cell system (1a; 1 c; 1d) according to one of the preceding

 Expectations,

 characterized in that

 downstream of the afterburner (5) a hot side of a

Reformer heat exchanger (10) of the fuel cell system (1 a; 1 c; 1 d) is configured and the exhaust gas catalytic converter (6) is arranged downstream of the hot side of the reformer heat exchanger (10).

6. Fuel cell system (1 a; 1d) according to one of the preceding claims, characterized in that

 downstream of the afterburner (5), an afterburner exhaust branching section (20) for branching afterburner exhaust gas onto a hot side of a cathode gas heat exchanger (8)

 Fuel cell system (1 a; 1d) and / or on a hot side of a

 Reformer heat exchanger (10) of the fuel cell system (1 a; 1 d) is configured, the exhaust gas catalytic converter (6) being arranged downstream of the hot side of the cathode heat exchanger (8) and downstream of the hot side of the reformer heat exchanger (10).

7. fuel cell system (1 a; 1d) according to claim 6,

 characterized in that

 downstream of the afterburner (5) and upstream of the

 Afterburner exhaust branching section (20), the first mixing chamber (11) for mixing the afterburner exhaust with pure or substantially pure cathode exhaust gas is arranged.

8. fuel cell system (1 a; 1d) according to any one of claims 6 to 7,

 characterized in that

 downstream of the hot side of the cathode heat exchanger (8),

 a second mixing chamber (12) for mixing the afterburner exhaust gas downstream of the hot side of the cathode heat exchanger (8) and the afterburner exhaust gas is arranged downstream of the hot side of the reformer heat exchanger (10) downstream of the hot side of the reformer heat exchanger (10).

9. Fuel cell system (1a; 1 b; 1 c; 1 d) according to one of the preceding

 Expectations,

 characterized in that

 an ignition detection unit (13) for detecting an ignition and / or a combustion with flame formation in the gas combustion chamber (7) is at least partially provided on the afterburner (5).

10. Fuel cell system (1a; 1 b; 1 c) according to one of the preceding

Expectations, characterized in that

 the at least one fuel cell stack (2), the afterburner (5) and the exhaust gas catalyst (6) are arranged in a hot box (14) of the fuel cell system (1 a; 1 b; 1 c), an oxygen supply section (15) for supplying oxygen or an oxygen-containing fluid in the gas combustion chamber (7) is at least partially configured outside the hotbox (14).

11. Fuel cell system (1a; 1 b; 1 c) according to claim 10,

 characterized in that

 At least one temperature control means (16) for adjustable temperature control of the oxygen or the oxygen-containing fluid is arranged in the oxygen supply section (15).

12. Fuel cell system (1a; 1 b; 1 c; 1 d) according to one of the preceding

 Expectations,

 characterized in that

 an adjustment unit (9) is configured to adjust a combustion temperature in the gas combustion chamber (7) to a maximum of 1200 ° C.

13. Fuel cell system (1a; 1 b; 1 c; 1 d) according to one of the preceding

 Expectations,

 characterized in that

 an adjusting unit (9) for adjusting an anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber (7) is configured in a range between 3: 1 and 1: 1, in particular to approximately 2: 1.

14. A method for operating a fuel cell system (1 a; 1 b; 1 c; 1 d) according to one of the preceding claims,

 characterized in that

 in the gas combustion chamber (7) of the afterburner (5) combustion of anode exhaust gas is carried out with the formation of flames.

15. The method according to claim 14,

 characterized in that

Afterburner exhaust gas from the gas combustion chamber (7) is treated catalytically downstream and separated from the afterburner (5) by the exhaust gas catalytic converter (6).

16. The method according to claim 14 or 15,

 characterized in that

 Cathode exhaust gas upstream of the afterburner (5) via a

 Cathode exhaust branch (17) is divided, a first part via a first cathode exhaust branch (18) to the afterburner (5) and a second part via a second cathode exhaust branch (19) to a first mixing chamber (11).

17. The method according to any one of claims 14 to 16,

 characterized in that

 the combustion temperature in the gas combustion chamber (7) by the

 Adjustment unit (9) is set to a maximum of 1200 ° C.

18. The method according to any one of claims 14 to 17,

 characterized in that

 the anode exhaust gas / cathode exhaust gas ratio in the gas combustion chamber (7) by the adjusting unit (9) in a range between 3: 1 and 1: 1,

 in particular to about 2: 1.

19. Use of a fuel cell system (1 a; 1 b; 1 c; 1 d) according to any one of claims 1 to 13 for providing electrical energy in a stationary power plant.