DE102008009063A1 - Fuel cell system for use in motor vehicle i.e. commercial vehicle, has gas burner for burning hydrogenous anode exhaust gas, and oxidation catalyst provided with mixer structure for mixing gas flowing through oxidation catalyst - Google Patents

Abstract

The system (1) has a fuel cell (2) for generating electric current (5) from hydrogenous anode gas (6) and oxygenic cathode gas (7). A residual gas burner (3) is arranged downstream to the fuel cell for burning hydrogenous anode exhaust gas (13) by oxygenic cathode exhaust gas (15). An oxidation catalyst (24) is provided with a mixer structure (45) for mixing the gas flowing through the oxidation catalyst, where the mixer structure is catalytically and actively coated and comprises a piece of integral or separately manufactured structural element.

Description

The The present invention relates to a fuel cell system, in particular in a motor vehicle, having the features of the preamble of the claim 1.

From the DE 10 2004 033 545 A1 a residual gas burner for a fuel cell system is known, which is arranged downstream of the fuel cell. The fuel cell is used to generate electric current from hydrogen-containing anode gas and oxygen-containing cathode gas. The residual gas burner serves to burn hydrogen-containing anode exhaust gas and oxygen-containing cathode exhaust gas. With the help of the residual gas burner is thus trying to prevent emission of hydrogen and carbon monoxide into the environment. At the same time, an improvement in the overall efficiency of the fuel cell system is to be achieved by the implementation of the hydrogen contained in the anode exhaust gas and carbon monoxide.

From the DE 10 2006 046 257 from 28.09.2006 another fuel cell system of this kind is known in which an oxidation catalyst is arranged in the residual gas burner. An oneses fuel cell system with a reformer is from the DE 10 2006 017 616 known.

The The present invention addresses the problem of for a fuel cell system of the type mentioned to provide an improved embodiment, in particular by reduced pollutant emissions and / or by an increased Efficiency distinguishes.

This Problem is inventively by the subject of the independent claim. advantageous Embodiments are the subject of the dependent Claims.

The Invention is based on the general idea, the fuel cell system equipped with an oxidation catalyst, which also so is configured that he has a thermal homogenization of him flowing gas flow causes. Reached this is especially due to a mixture of him flowing through Gas flow, in particular a transverse mixture preferred can be. Through the use of such an oxidation catalyst the pollutant content in the burner exhaust gas can be reduced. Especially may still be contained in the gas flow in the oxidation catalyst Residual amounts of hydrocarbons are reacted. Through the integration a mixer structure in the oxidation catalyst is a homogenization the gas flow flowing through the catalyst reached. The aim here is a homogenization with regard to the temperature distribution within the flow cross section. hereby On the one hand, the conversion rate of the catalyst can be improved. On the other hand, this can be the thermal load reduce the catalyst, which extends its life. About that In addition, a gas flow with thermally homogeneous cross-section in an optionally downstream heat exchanger with an increased transmission efficiency the heat to a suitable heat transfer medium be used. Accordingly, the burner exhaust gas can be withdraw more heat energy downstream of the catalyst, which reduces the heat losses of the fuel cell system and thus increases its efficiency.

Corresponding In an advantageous embodiment, the mixer structure be catalytically active coated. In this way receives a mixer structure optimized for the cross mixing function the functionality of the oxidation catalyst. This can an integrated design can be realized, the extremely space-saving is. Particularly advantageous is a development in which the Oxidation catalyst through the catalytically active coated mixer structure is formed. That is, the oxidation catalyst exclusively in this embodiment the catalytically active structure is, of course optionally arranged in a corresponding housing can be.

The Mixer structure, for example, one in the gas path of the gas flow arranged, can be flowed through by the gas flow be porous structure, in particular catalytically active can be coated. Such porous structures are for example, in particle filters known that a ceramic body exhibit. Likewise, porous structures are, for example known in pore burners, which also has a ceramic body exhibit. Such a porous structure enforces their flow through an intense cross mixture. about the pore size or pore density of the porous Structure can adjust its flow resistance to a suitable value be set.

Alternatively, the mixer structure may also be a directional or non-directional arrangement of fibers or wires, e.g. In the form of a fabric or a grid or a mat, each consisting of fibers or wires. The fibers or wires used in each case can be coated in particular catalytically active. A mixer structure formed from fibers or wires can likewise be produced comparatively easily and can likewise have very large surfaces, which is advantageous for the catalyst effect. In this case, ordered structures, such as in a fabric or a grid, can be used, as well as disordered or amorphous Structures, such as a mat or a ball-like arrangement. Such fiber or wire structures are relatively flexible and thus easy to install. The wires or fibers are preferably made of a suitable metal.

alternative For example, the mixer structure may also have a multilayer sheet-metal structure have, whose metal sheets pass through channels Make Miteinan via cross-connection opening of the communicate, wherein the metal sheets in particular catalytically active can be coated. The metal sheets, in particular are made of metal, allow in particular the Realization of a mixer structure with a relatively small flow resistance. The cross connection openings make it possible the cross-mixing of the flow over each adjacent channels.

A Metallic mixer structure is also characterized from that over the metal a certain heat conduction can be achieved, the thermal homogenization of the gas flow also contributes without cross mixing of the gas flow.

in principle can the oxidation catalyst downstream of the residual gas burner in a Exhaust pipe can be arranged, the burner exhaust gas from the residual gas burner dissipates. Here, the oxidation catalyst may preferably Located upstream of a heat exchanger, the can also be arranged in the exhaust pipe to heat to withdraw from the burner exhaust gas to this elsewhere, z. B. in the fuel cell system to use. The arrangement of the oxidation catalyst upstream of the heat exchanger has the advantage that also the heat over the heat exchanger the Burner exhaust gas can be withdrawn, the exhaust aftertreatment optionally obtained in the oxidation catalyst.

alternative the oxidation catalyst can be arranged in the residual gas burner in such a way that during operation of the fuel cell system burner exhaust gas downstream of the oxidation catalyst emerges from the residual gas burner. This results in a fuel cell system for a extremely compact design, as the oxidation catalyst in the residual gas burner is integrated and in this regard no separately be arranged Component forms.

According to one advantageous embodiment, the residual gas burner contains a combustion chamber in which the combustion of anode exhaust gas and cathode exhaust gas takes place. The oxidation catalyst is then downstream of this combustion chamber arranged and may preferably be designed so that in the oxidation catalyst an implementation of contained in the combustion exhaust gas of the combustion chamber Carbon monoxide is made in carbon dioxide. In this embodiment can Thus, the carbon monoxide emission can be significantly reduced. These Embodiment is of particular advantage for Fuel cells designed as high-temperature fuel cells are.

at an alternative embodiment, the residual gas burner contain a mixing space in which mix the anode exhaust gas and the cathode exhaust gas. In this embodiment, the oxidation catalyst is arranged downstream of the mixing chamber and may be appropriate be configured so that the combustion in the oxidation catalyst of anode exhaust and cathode exhaust gas, that is the conversion of hydrogen and carbon monoxide takes place. In this embodiment the residual gas burner works catalytically, since the actual combustion reaction, namely the implementation of the fuel, so the hydrogen and carbon monoxide, in the catalyst. As far as that is concerned it is then a catalytic residual gas burner. This embodiment is of particular advantage for a fuel cell, the is designed as a low-temperature fuel cell. It allows the catalytic residual gas burner an efficient implementation of the residual content at hydrogen in the anode exhaust gas. At the same time the emission of Carbon monoxide comparatively low, since the low-temperature fuel cell usually anyway receives very little carbon monoxide on the input side anyway.

Further important features and advantages of the invention will become apparent from the Subclaims, from the drawings and from the associated Description of the figures with reference to the drawings.

It it is understood that the above and the following yet to be explained features not only in each case specified combination, but also in other combinations or can be used in isolation, without the scope of the present To leave invention.

preferred Embodiments of the invention are in the drawings and will become more apparent in the following description explained, wherein the same reference numerals to the same or similar or functionally identical components relate.

It show, in each case schematically,

1 to 6 in each case a greatly simplified circuit diagram-like basic representation of a fuel cell system in various embodiments,

7 to 11 in each case a greatly simplified schematic representation of a mixer structure in various embodiments.

According to the 1 to 6 includes a fuel cell system 1 at least one fuel cell 2 and a residual gas burner 3 , Furthermore, the fuel cell system 1 at least one heat exchanger 4 exhibit. In addition, the fuel cell system can 1 in the usual way include other components, such as. B. a reformer for generating hydrogen-containing anode gas from a hydrocarbon fuel such. As diesel, biodiesel, gasoline and any synthetic fuels, and at least one other heat exchanger. The fuel cell system 1 is preferably used in a motor vehicle, in particular in a commercial vehicle, and can be used there as an additional power source which operates independently of an internal combustion engine of the vehicle. For example, with the help of the fuel cell system 1 be switched off the internal combustion engine, an air conditioner of the vehicle to be operated. Similarly, the entire power supply of the vehicle with the fuel cell system 1 will be realized.

The fuel cell 2 is used to generate electricity 5 from hydrogen-containing anode gas 6 and oxygen-containing cathode gas 7 , For this purpose, the fuel cell contains 2 an anode side 8th and a cathode side 9 which is usually due to an electrolyte 10 are separated from each other. With the help of the electrolyte 10 there is a generation of electricity from anode gas 6 and cathode gas 7 in which hydrogen is reacted with oxygen electrochemically and thereby electrical energy is released. The fuel cell 2 usually consists of a stack of fuel cell elements or fuel cell plates. In the 1 to 6 is just an end plate 11 shown. The end plate 11 has an anode exhaust outlet 12 , from the hydrogen-containing anode exhaust gas 13 from the fuel cell 2 exit, as well as a cathode exhaust gas outlet 14 on, from the oxygen-containing cathode exhaust gas 15 from the fuel cell 2 exit. Furthermore, the fuel cell 2 an anode gas inlet 16 through which the anode gas 6 into the fuel cell 2 enters, and a cathode gas inlet 17 on, through which the cathode gas 7 into the fuel cell 2 entry. At least one electrical connection 18 is the electricity 5 at the fuel cell 2 tapped.

When Cathode gas is preferably used air. As an anode gas can pure hydrogen gas, e.g. B. from a hydrogen tank, or a hydrogen-containing synthesis gas can be used, the z. B. off an oxygen-containing oxidizer gas and a hydrocarbon fuel is generated.

To supply the fuel cell 2 with cathode gas is the fuel cell system 1 for example, with a cathode gas supply 37 equipped to an input side of the fuel cell 2 connected. The cathode gas supply 37 has a cathode gas line 38 on, at the cathode gas entrance 17 is connected and the one conveyor 39 , z. B. a fan contains.

The residual gas burner 3 is downstream of the fuel cell with respect to the anode-side and cathode-side gas streams 2 arranged. The residual gas burner 3 serves to burn the anode exhaust gas 13 and the cathode off-gas 15 , For this purpose, the residual gas burner 3 an anode exhaust inlet 19 on, through the anode exhaust 13 in an anode exhaust path 20 of the residual gas burner 3 can occur. Furthermore, the residual gas burner 3 a cathode exhaust inlet 21 on, through the cathode exhaust gas 15 in a cathode exhaust path 22 of the residual gas burner 3 can occur.

In the residual gas burner 3 is a room 23 formed, in which the cathode exhaust gas 15 through the cathode exhaust path 22 and the anode exhaust gas 13 through the anode exhaust path 20 can occur. The function of the room 23 will be explained in more detail below.

The fuel cell system 1 also has an oxidation catalyst 24 on. This can, as in the embodiments of 1 to 4 in the residual gas burner 3 be arranged. Likewise, the oxidation catalyst 24 according to the embodiments of 5 and 6 concerning the residual gas burner 3 be designed as a separate component and be subordinate to this.

In the embodiments of the 1 to 4 is the oxidation catalyst 24 thus in the residual gas burner 3 integrated. Only downstream of the oxidation catalyst 24 occurs burner exhaust 25 from the residual gas burner 3 out. The catalyst 24 closes in the residual gas burner 3 downstream to the room 23 at. In contrast, the oxidation catalyst 24 in the embodiments of the 5 and 6 downstream of the residual gas burner 3 in a likewise with 25 designated exhaust pipe, which is the burner exhaust gas 25 from the residual gas burner 3 leads away.

The oxidation catalyst 24 is with a mixer structure 45 equipped, which is designed so that the oxidation catalyst 24 flowing gas flow is mixed in view of a homogenization of the temperature in the flow-through cross-section. For example, the gas flow can be cross-mixed, ie mixed transversely to its main flow direction. In principle, the oxidation catalyst 24 this mixer structure 45 and additionally have a catalyst structure, not shown here, whereby the different functions can be realized in separate components. The catalyst structure can then in principle be produced in any desired manner, for example with a carrier made of ceramic or of metal, as well as a catalytic coating.

Preferred is the embodiment shown here, in which the mixer structure 45 itself catalytically active coated, in which case it is basically possible to dispense with a separate catalyst structure. Accordingly, in the embodiments shown here, the catalyst 24 through the catalytically active coated mixer structure 45 educated. The two functionalities, namely the catalyst effect and the mixing effect, are thus realized in a single component. The catalyst 24 builds extremely compact.

To the residual gas burner 3 can according to the 1 to 6 preferably a cooling gas supply 26 be connected. The cooling gas supply 26 includes a cooling gas line 27 in which a conveyor 28 , z. B. a cooling gas pump or a cooling gas fan is arranged. The cooling gas line 27 is to the input side, preferably to the cathode side of the residual gas burner 3 connected. In the present case, the cooling gas line communicates 27 with the cathode exhaust path 22 , Preferably, an oxygen-containing gas, in particular air, is used as the cooling gas.

Furthermore, a controller 29 be provided, on the one hand with the cooling gas supply 26 and on the other hand with a sensor 30 connected is. Preferably, the controller 29 as here also with the cathode gas supply 37 connected. The sensors 30 serves to determine a temperature of the oxidation catalyst 24 , For this purpose, the sensors 30 at least one temperature sensor 31 exhibit. Said temperature sensor 31 can at the catalyst inlet, in the catalyst 24 at the catalyst outlet or downstream of the catalyst 24 be arranged. About corresponding unspecified signal lines receives the controller 29 with the temperature of the catalyst 24 correlating signal values. The sensors 30 Can also use a flame sensor 32 be equipped in the room 23 is arranged and with the help of the presence or absence of a flame in the room 23 is detectable. The control 29 is z. B. with the conveyor 28 the cooling gas supply 26 connected. In addition, the controller 29 also with an ignition device 33 be connected. Likewise, the controller 29 with the conveyor 39 the cathode gas supply 37 be connected. The control 29 can by appropriate control signals the conveyors 28 . 39 as well as the ignition device 33 actuate. Corresponding control lines are not designated. The control 29 can be used to realize a temperature control for the catalyst 24 be designed.

In addition, the sensors can 30 at least one lambda probe 40 and / or at least one pressure sensor 40 exhibit. For the respective lambda probe 40 or for the respective pressure sensor 40 Basically, the same arrangement possibilities exist as for the at least one temperature sensor 31 , Accordingly, in the figures for simplified representation, the reference numerals 31 for the temperature sensor and 40 for the lambda probe or for the pressure sensor in each case to identify the same components verwen det, so that it is optional in the respective component to a temperature sensor 31 or a lambda probe 40 or a pressure sensor 40 or a combination of these can act. The respective lambda probe 40 or the respective pressure sensor 40 is via corresponding unspecified signal lines also with the controller 29 connected.

The heat exchanger 4 is on the one hand in the flow of burner exhaust gases 25 or in the exhaust pipe 25 and, on the other hand, into a stream of a suitable heat transfer medium 34 involved. The heat exchanger 4 allows in the usual way a heat transfer to the heat transfer medium 34 without a fluid exchange between the heat transfer medium 34 and the burner exhaust 25 , For example, it is the heat transfer medium 34 to a process medium of the fuel cell system 1 , z. B. to that of the fuel cell 2 supplied cathode gas 7 and / or around the above-mentioned reformer supplied oxidizer gas and / or supplied to the reformer or the oxidizer gas water. It may also be the heat transfer medium 34 to the cooling liquid of a cooling circuit of the fuel cell system 1 equipped vehicle act. In the embodiments of the 1 . 2 . 4 and 5 is the oxidation catalyst 24 upstream of the heat exchanger 4 while he is in the embodiments of the 3 and 6 in the heat exchanger 4 is integrated. In this way, the heat that is in the exhaust aftertreatment in the catalyst 24 if necessary set free, in the heat exchanger 4 be used to transfer them to the respective heat transfer medium 34 transferred to.

If the heat exchanger 4 for heating an educt of the fuel cell system 1 serves, can be followed by at least one additional heat exchanger, with the z. B. a vehicle heating can be operated. The conveyor 39 of the 1 to 6 is expedient stream on the heat exchanger 4 in the cathode gas line 38 arranged when passing through the Heat exchanger 4 is performed, as a heat transfer medium 34 Serving cathode gas for the fuel cell 2 preheat.

In a first variant of the in the 1 to 6 shown embodiments, the room serves 23 mainly as a combustion chamber 35 in which the combustion of anode exhaust gas with cathode exhaust gas, ie the conversion of hydrogen, takes place during operation of the fuel cell system 1. In this embodiment, the oxidation catalyst is 24 in any case designed so that therein a conversion of carbon monoxide in the combustion exhaust gas of the combustion chamber 35 contained in carbon dioxide. It is clear that in the catalyst 24 also a reaction of residual hydrogen or residual hydrocarbons takes place. The catalyst 24 serves mainly or exclusively for the reduction of pollutant emissions. This first alternative is particularly suitable for use in a fuel cell 2 The working temperature of such a high-temperature fuel cell is at a maximum of about 850 ° C. The exhaust gas temperatures of this type of fuel cell are sufficiently high to reach the combustion chamber 35 to achieve a stable combustion reaction.

In a second alternatives in the 1 to 4 shown embodiments, the space 23 predominantly as a mixing room 36 serve. In the mixing room 36 there is a thorough mixing of the anode exhaust gas entering therein 13 with the cathode exhaust gas also entering it 15 , The oxidation catalyst 24 is now designed to be therein during operation of the fuel cell system 1 the combustion of anode exhaust gas 13 with cathode exhaust 15 , That is, the implementation of the hydrogen and, if present, the carbon monoxide takes place. In this second variant, the residual gas burner works 3 catalytically or is the residual gas burner 3 designed as a catalytic burner. For the start of this catalytic burner ignition of a flame may be provided to the catalyst structure or the oxidation catalyst 24 as quickly as possible to bring the activation temperature. For this purpose, again a corresponding ignition device 33 to be available. In particular, the residual gas burner 3 be designed in these embodiments as a catalytic structure burner or catalytic pore burner, which is also suitable as a mixer. This will be explained below with reference to the 7 to 10 discussed in more detail. This alternative is particularly suitable for use in a fuel cell 2 , which is designed as a low-temperature fuel cell. For example, this is a fuel cell 2 The working temperature of such a low-temperature fuel cell is at a maximum at about 80 ° to 150 ° C. A fuel cell system with such a CO purification device is, for example, made of of the DE 20 2006 008 898 U1 known.

Known low-temperature fuel cells, in particular PEM fuel cells, are extremely sensitive to carbon monoxide. Accordingly, a reformer, not shown, for generating the anode gas 6 Usually downstream of a CO purification device to extract the carbon monoxide formed during the reforming process the synthesis gas, so this as largely free of carbon monoxide anode gas 6 the fuel cell 2 can be supplied.

Furthermore, it is customary in a low-temperature fuel cell, in particular in a PEM fuel cell, the cathode gas 7 to provide a relatively high proportion of water vapor. The water supports the fuel cell process on the electrolyte 10 , Accordingly, according to the 1 to 3 the fuel cell system 1 optionally with an infeed device 41 be equipped with the help of water vapor in the cathode gas 7 can be introduced. The feeding device 41 For this purpose, for example, upstream of the cathode gas input 17 in the cathode gas line 38 arranged. For the combustion process in the residual gas burner 3 , especially in the event that the residual gas burner 3 operated as a catalytic burner, a high water content in the mixture is undesirable. Accordingly, optionally, a removal device 42 be provided. With the help of the removal device 42 can the cathode exhaust gas 15 To be deprived of water vapor. Preferably, the removal device 42 for this purpose in a cathode exhaust gas line 43 arranged, which the cathode exhaust gas outlet 14 the fuel cell 2 with the cathode exhaust inlet 21 of the residual gas burner 3 combines. Between the withdrawal facility 42 and the feeding device 41 can be an active compound 44 exist, which is indicated here by a broken line. Through this active connection 44 Can the with the help of the removal device 42 the cathode exhaust gas 15 removed water vapor of the feed device 41 for feeding into the cathode gas 7 be supplied. This active compound 44 may contain a conveyor for water or water vapor. Particularly advantageous is an embodiment in which the feed device 41 and the withdrawal facility 42 form a structural unit, so that the active compound 44 is arranged inside such a combined feed and removal device. The use of such a combined feed and withdrawal direction is, for example, by a corresponding course of the cathode exhaust gas line 43 and / or the cathode gas line 38 realizable.

To start the combustion reaction in the room 23 , in particular for activating the catalyst 24 , Preferably, in the second variant, the controller 29 the ignition device 33 actuate. About the flame sensor 32 can the controller 29 monitor whether the desired combustion reaction is proceeding properly. In the second variant, the room serves 23 during startup as a combustion chamber 35 , wherein the air / fuel ratio lambda is suitably greater than 1 to choose. Once the catalyst 24 has reached its start temperature, "migrates" the combustion reaction into the catalyst 24 , Then the room serves 23 then as a mixing room 36 , About the sensors 30 monitors the controller 29 the temperature of the catalyst 24 , In both alternatives it is desirable to overheat the catalyst 24 to avoid. The control 29 can now depend on the temperature of the oxidation catalyst 24 the cooling gas supply 26 actuate. The temperature of the catalyst approaches 24 a critical upper temperature range, the z. B. may be about 1,000 ° C, the controller 29 the supply of cooling gas in the room 23 turn on or amplify, causing the concentration of hydrogen in the room 23 reduced. Alternatively or additionally, the controller 29 also the volume flow for the supply of the fuel cell 2 with cathode gas 7 increase, provided the operating window of the fuel cell 2 this allows. The increased amount of cathode gas also increases the residual gas burner 3 supplied cathode exhaust gas amount, which is also a cooling of the residual gas burner 3 or of the catalyst 24 causes. As a result, the temperature in the combustion chamber decreases 35 or in the catalyst 24 from. Cools the catalyst 24 Too much can, by reducing or switching off the Kühlgaszumischung or by reducing the cathode gas supply of the fuel cell 2 a corresponding increase in temperature be brought about.

The control 29 can in principle be designed so that they control the temperature of the residual gas burner 3 or of the catalyst 24 initially only by a corresponding actuation of the cathode gas supply 37 or their conveyor 39 realized, if this is the current operating window of the fuel cell 2 allows. Only then, if the required cooling capacity can not be achieved by increasing the cathode gas volume flow, does the controller activate 29 the cooling gas supply 26 to realize the necessary cooling by supplying cooling gas.

In the in the 1 and 4 to 6 embodiments shown is the heat exchanger 4 with respect to the exhaust gas flow downstream of the residual gas burner 3 arranged and forms in this regard a separate component. In contrast, the heat exchanger 4 in the embodiments of the 2 and 3 in the residual gas burner 3 integrated. Suitably forms the heat exchanger 4 an outlet-side completion of the residual gas burner 3 , The fuel cell system 1 thus builds comparatively compact with respect to these components.

At the in 2 embodiment shown is the heat exchanger 4 in the residual gas burner 3 downstream of the catalyst 24 arranged. In contrast, in the embodiment according to 3 the oxidation catalyst 24 in the heat exchanger 4 integrated. Also at the in 6 embodiment shown is the oxidation catalyst 24 in the heat exchanger 4 integrated, but this unit downstream of the residual gas burner 3 is arranged. It is also possible this unit of heat exchanger 4 with integrated oxidation catalyst 24 on the output side directly to the residual gas burner 3 grow. The integration of the oxidation catalyst 24 in the heat exchanger 4 can be realized, for example, that a catalytically active coating of the heat exchanger 4 within the burner exhaust 25 associated fluid path is provided. In these embodiments, the residual gas burner builds 3 or the heat exchanger 4 and thus the fuel cell system equipped with it 1 very compact.

In the embodiments of the 1 to 3 . 5 and 6 is the residual gas burner 3 with regard to the fuel cell 2 designed as a separate component and accordingly downstream of the fuel cell 2 arranged. At the in 4 embodiment shown is the residual gas burner 3 to the fuel cell 2 grown on the output side or outflow side. Accordingly, the residual gas burner 3 also downstream of the fuel cell in this embodiment 2 arranged. It is particularly advantageous in the embodiment according to 4 that the residual gas burner 3 the end plate 11 the fuel cell 2 forms. This allows the fuel cell exhaust gases 13 . 15 internally the residual gas burner 3 respectively. The fuel cell system 1 builds extremely compact. It is clear that in 4 embodiment shown as well with the peculiarities of the embodiments of 2 and 3 can be combined. Accordingly, in the embodiment according to 4 the heat exchanger 4 in the residual gas burner 3 be integrated. In addition, the catalyst can also 24 in the heat exchanger 4 be integrated.

The following is based on the 7 to 10 without restriction of generality tert, as the mixer structure 45 basically can be constructed.

Corresponding 7 can the mixer structure 45 for example, a porous structure 46 exhibit. This porous structure 46 is in a gas path 47 arranged here symbolized by arrows. Along this gas path 27 becomes the catalyst 24 or the mixer structure 45 flows through the respective gas flow. The gas flow is preferably the burner exhaust gas 25 or according to an embodiment also explained about the fuel-oxidizer mixture. The porous structure 46 can be realized by means of a ceramic component. Such ceramic components, in particular monoliths, are used, for example, in the production of particle filters. Likewise, for example, a pore burner may have a suitable porous structure. Likewise, metallic porous structures are conceivable, such. B. metal foams. According to a particularly expedient embodiment, the porous structure 46 be coated with a suitable catalyst mate rial. A catalytically active coating of this type can be realized for example with platinum, rhodium and / or palladium.

Corresponding 8th can the mixer structure 45 can also be realized by means of fibers or wires that form a tissue 48 or to a grid 48 are processed. In this way, a structured arrangement of the fibers or wires can be realized, whereby in particular a high load capacity for the mixer structure 45 with high flexibility is feasible. Again, it is possible to coat the fibers or wires catalytically active.

9 shows an embodiment in which the mixer structure 45 through a mat 49 is formed, which also consists of fibers or wires, but which are arranged unstructured or amorphous. These fibers or wires can be catalytically active coated.

Finally shows 10 an embodiment in which the mixer structure 45 a multi-layer sheet metal structure 50 having. This is made of several metal sheets 51 constructed, which are laminated in a suitable manner, such that between adjacent metal sheets 51 flow-through channels 52 form. Furthermore, the metal sheets have 51 Crossover apertures 53 through which adjacent channels 52 communicate with each other. This cross-exchange between adjacent channels 52 can with the help of flow control elements 54 reinforced, in the area of the transverse openings 53 on the metal sheets 51 can be provided. In particular, such flow guide can be 54 form in that when making the transverse openings 53 Subareas of the respective metal sheet 51 punched and angled, taking with the respective sheet metal 51 stay connected. Also in this embodiment can be provided, the sheet metal web structure 50 catalytically active coating in a suitable manner.

11 shows a greatly simplified longitudinal section through the mixer structure 45 in a particular embodiment, wherein the mixer structure 45 one of the in the 7 to 10 may have shown designs or any other suitable design. Corresponding 11 may be the catalytic coating of the oxidation catalyst 24 or the mixer structure 45 In this case, in the longitudinal direction, that is to say in the direction of flow, it may be designed in such a way that the catalytic activity of the coating in the direction of flow through the catalyst 24 or the mixer structure 45 gradually increases. In this case, two or more successive stages can be provided with increasing reactivity. As a result, the reaction reaction along the flow direction can be homogenized, which reduces the thermal load of the respective component. In addition or as an alternative, an input-side first stage can also be uncoated, ie not catalytically actively coated, which increases the thermal load on the mixer structure 45 reduced at the input side. In the example of 11 are three levels without restriction of generality 55 . 56 and 57 shown, which are arranged axially one behind the other. The flow direction is here by arrows 58 indicated, causing the mixer structure 45 an entry page 59 and an exit side 60 To be defined. In the example, therefore, an input-side or first stage 55 , a middle or second stage 56 and an output-side or third stage 57 available. In particular, it can now be provided that the first stage 55 catalytically inactive, that has no catalytically active coating, while the second and third stage 56 . 57 catalytically active coated. Accordingly, the catalytically active coating in the flow direction 58 a distance from the input side 59 on. The two coated steps 56 and 57 differ from one another in the catalytic reactivity of their coatings. The first through-flowed second stage 56 has a weaker catalytic activity than the subsequently passed third stage 57 , The individual stages 55 . 56 . 57 can be integrally formed in a common structural element. It is also possible, at least one of the stages 55 . 56 . 57 form in a separate structural element, with at least one other structural element to the mixer structure 45 is assembled. For example, it may be for the manufacturability of the mixer structure 45 with stepped catalytic advantageous coating, the uncoated first stage 55 separately from one of the two other coated stages 56 . 57 To produce structure element, so as to the mixer structure 45 assemble. Also, the two catalytically active stages 56 . 57 be produced by means of separate structural elements.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102004033545 A1 [0002]
• - DE 102006046257 [0003]
• - DE 102006017616 [0003]
• - DE 202006008898 U1 [0038]

Claims (14)

Fuel cell system, in particular in a motor vehicle, - with a fuel cell ( 2 ) for generating electricity ( 5 ) of hydrogen-containing anode gas ( 6 ) and oxygen-containing cathode gas ( 7 ), - with a fuel cell downstream ( 2 ) arranged residual gas burner ( 3 ) for burning hydrogen-containing anode exhaust gas ( 13 ) with oxygen-containing cathode exhaust gas ( 15 ), characterized by an oxidation catalyst ( 24 ) with a mixer structure ( 45 ) for mixing an oxidation catalyst ( 24 ) flowing gas flow. Fuel cell system according to claim 1, characterized in that the mixer structure ( 45 ) is coated catalytically active, wherein in particular the oxidation catalyst ( 24 ) by the catalytically active coated mixer structure ( 45 ) can be formed. Fuel cell system according to claim 2, characterized in that the catalytically active coating in the flow direction of the mixer structure ( 45 ) is stepped, such that the catalytic activity increases in the flow direction stepped, wherein in particular additionally or alternatively it can be provided that the catalytically active coating in the flow direction ( 58 ) from an input side ( 59 ) of the mixer structure ( 45 ), wherein in particular the mixer structure ( 45 ) can be assembled from one piece integral or from a plurality of separately produced structural elements. Fuel cell system according to one of claims 1 to 3, characterized in that the mixer structure ( 45 ) one in the gas path ( 47 ) arranged in the gas flow, can be flowed through by the gas flow porous structure ( 46 ), which in particular may be catalytically active coated. Fuel cell system according to one of claims 1 to 3, characterized in that the mixer structure ( 45 ) a tissue ( 48 ) or a grid ( 48 ) or a mat ( 49 ) is in each case made of fibers or wires, which in particular can be coated catalytically active. Fuel cell system according to one of claims 1 to 3, characterized in that the mixer structure ( 45 ) a multilayer sheet-metal web structure ( 50 ) whose metal sheets ( 51 ) through-flow channels ( 52 ), which via cross-connection opening ( 53 ) communicate with each other, the sheet-metal web structure ( 50 ) may be coated in particular catalytically active. Fuel cell system according to one of claims 1 to 6, characterized in that the oxidation catalyst ( 24 ) in the residual gas burner ( 3 ) is arranged so that during operation of the fuel cell system ( 1 ) Burner exhaust gas ( 25 ) downstream of the oxidation catalyst ( 24 ) from the residual gas burner ( 3 ) exit. Fuel cell system according to claim 7, characterized in that the residual gas burner ( 3 ) a combustion chamber ( 35 ) in which in operation of the fuel cell system ( 1 ) the combustion of anode exhaust gas ( 13 ) with cathode exhaust gas ( 15 ) takes place, wherein the oxidation catalyst ( 24 ) downstream of the combustion chamber ( 35 ) and is configured such that during operation of the fuel cell system ( 1 ) in the oxidation catalyst ( 24 ) a conversion of in the combustion exhaust gas of the combustion chamber ( 35 Carbon monoxide contained in carbon dioxide, in particular the fuel cell ( 2 ) may be configured as a high-temperature fuel cell. Fuel cell system according to claim 7, characterized in that the residual gas burner ( 3 ) a mixing room ( 36 ) in which in operation of the fuel cell system ( 1 ) the anode exhaust gas ( 13 ) and the cathode exhaust gas ( 15 ), wherein the oxidation catalyst ( 24 ) downstream of the mixing chamber ( 36 ) and is configured such that during operation of the fuel cell system ( 1 ) in the oxidation catalyst ( 24 ) the combustion of anode exhaust gas ( 13 ) with cathode exhaust gas ( 15 ) takes place, in particular the fuel cell ( 2 ) may be configured as a low-temperature fuel cell. Fuel cell system according to one of claims 1 to 9, characterized in that - to the residual gas burner ( 3 ) on the input side a cooling gas supply ( 26 ), that a sensor system ( 30 ) for determining the temperature of the oxidation catalyst ( 24 ) is provided, - that one with the cooling gas supply ( 26 ) and with the sensors ( 30 ) connected control ( 29 ) for operating the cooling gas supply ( 26 ) as a function of the temperature of the oxidation catalyst ( 24 ) is provided. Fuel cell system according to one of claims 1 to 10, characterized in that - to the fuel cell ( 2 ) on the input side, a cathode gas supply ( 37 ), that a sensor system ( 30 ) for determining the temperature of the oxidation catalyst ( 24 ) is provided, - that one with the cathode gas supply ( 37 ) and with the sensors ( 30 ) connected control ( 29 ) for operating the cathode gas supply ( 37 ) in Dependence of the temperature of the oxidation catalyst ( 24 ) is provided. Fuel cell system according to claims 10 and 11, characterized in that the controller ( 29 ) is configured so that when operating the cooling gas supply ( 26 ) the operation of the cathode gas supply ( 37 ) considered. Fuel cell system according to one of claims 1 to 12, characterized in that - downstream of the residual gas burner ( 3 ) a heat exchanger ( 4 ) for heat transfer to a heat transfer medium ( 34 ), which in particular downstream of the oxidation catalyst ( 24 ) in the residual gas burner ( 3 ), or - that in the residual gas burner ( 3 ) a heat exchanger ( 4 ) for heat transfer to a heat transfer medium ( 34 ), wherein in particular the oxidation catalyst ( 24 ) in the form of a catalytically active coating in the heat exchanger ( 4 ) can be integrated. Fuel cell system according to one of claims 1 to 13, characterized in that the residual gas burner ( 3 ) an end plate ( 11 ) of the fuel cell ( 2 ).