EP1456899A2

EP1456899A2 - Fuel cell structure and method for the operation of a fuel cell structure

Info

Publication number: EP1456899A2
Application number: EP02795134A
Authority: EP
Inventors: Marc Steinfort; Gerhard Huppmann
Original assignee: MTU CFC Solutions GmbH
Current assignee: MTU CFC Solutions GmbH
Priority date: 2001-12-15
Filing date: 2002-12-10
Publication date: 2004-09-15
Also published as: WO2003052857A3; DE10161838A1; CA2470188A1; WO2003052857A2; US20050158598A1; JP2005513720A

Abstract

Disclosed is a fuel cell structure comprising fuel cells, each of which contains an anode (1) and a cathode (2). Fresh air is admitted to the cathode inlet (KI) by means of a fresh air inlet (18, 19). A combustion device (16) is disposed between the anode outlet (AO) and the cathode inlet (KI) via an anode waste gas recirculation line (17) for post-combusting combustible residual components contained in the used fuel gas emitted from the anode outlet (AO), optionally in combination with fresh air admitted via the fresh air inlet (18, 19). The fresh air inlet (18, 19) comprises a first fresh air feeding pipe (18) connected to the combustion device (16) for optionally admitting fresh air to the combustion device (16) along with the used fuel gas, and a second fresh air feeding pipe (19) for admitting fresh air to the cathode inlet (KI) while bypassing the combustion device (16). The quantity of fresh air admitted to the combustion device (16) via the first fresh air feeding pipe (18) is preferably regulated in such a way that a temperature between 750 °C and 1400 °C, preferably between 850 °C and 1250 °C, is obtained in the combustion device (16) so as to accomplish a hot burner with the combustion device (16) in which fewer or no inert catalytic converters at all need to be used.

Description

Fuel cell arrangement and method for operating a fuel cell arrangement

The invention relates to a fuel cell arrangement according to the preamble of claim 1. Furthermore, the invention relates to a method for operating such a fuel cell arrangement.

Fuel cell arrangements are known in which the fuel cells each contain an anode and a cathode, and which have an anode input for supplying fresh fuel gas to the anodes and an anode output for discharging used fuel gas from the anodes, and a cathode input for supplying fresh cathode gas the cathodes and a cathode outlet for discharging used cathode gas from the cathodes, as well as a fresh air supply for supplying fresh air to the cathode inlet and a burner device connected via an anode exhaust gas recirculation line between the anode outlet and the cathode inlet for afterburning in the anode outlet Send spent combustible constituents contained in combustible gas, optionally together with fresh air supplied via the fresh air supply.

In previously known fuel cell arrangements, the burner device contains a catalytic burner in which the combustible residual components of the used fuel gas are burned together with the fresh air supplied from outside at temperatures between approximately 500 to 700 ° C. These comparatively low combustion temperatures are to be attributed to the fact that in the known fuel cell arrangements the practically total amount of the fresh air supplied and possibly the cathode exhaust gas, which is also partly returned from the cathode outlet to the burner device, did not allow higher combustion temperatures for energy reasons, so that combustion without a catalyst, which is generally expensive and requires defined operating temperatures was impossible.

The object of the invention is to provide a fuel cell arrangement of the type mentioned, in which the combustible residual components in the used anode fuel gas are burned at a higher temperature. Furthermore, the invention is intended to provide a method for operating such a fuel line arrangement.

The invention provides a fuel cell arrangement with one or more fuel cells, each containing an anode and a cathode, with an anode inlet for supplying fresh fuel gas to the anodes and an anode outlet for discharging used fuel gas from the anodes, with a cathode inlet for Supply of fresh cathode gas to the cathodes and a cathode outlet for discharging used cathode gas from the cathodes, with a fresh air supply for supplying fresh air to the cathode input and with a burner device for afterburning connected between the anode outlet and the cathode inlet via an anode exhaust gas recirculation line of combustible residual components contained in the spent fuel gas leaving the anode outlet, optionally together with fresh air supplied via the fresh air supply. According to the invention, the fresh air supply is a first fresh air supply line connected to the burner device for optional supply of fresh air together with the used fuel gas to the burner device and a second fresh air supply line for supplying fresh air to the cathode input bypassing the burner device.

A major advantage of the fuel cell arrangement according to the invention is that the combustible residual components in the used fuel gas can be burned at a higher temperature, so that fewer noble catalysts can be used in the burner device or catalysts can even be dispensed with entirely.

Control devices are preferably provided for setting the fresh air quantities supplied via the first fresh air supply line and the second fresh air supply line.

Furthermore, respective fans for conveying adjustable amounts of fresh air are preferably provided in the first fresh air supply line or the second fresh air supply line.

According to a preferred development of the fuel line arrangement according to the invention, a cathode exhaust gas return line coupled between the cathode outlet and the burner device and / or the cathode inlet is provided for returning at least part of the cathode exhaust gas to the burner device and / or the cathode inlet.

The cathode exhaust gas return line is preferably to

Returning part of the cathode exhaust gas to the burner device and returning part of the cathode exhaust gas to the cathode input, preferably via the second fresh air supply line, coupled to the cathode input, where preferably a control valve is provided for setting the ratio of the amounts of cathode exhaust gas returned to the burner device or to the cathode inlet.

The burner device preferably contains a burner for burning the combustible residual constituents contained in the anode exhaust gas and a heating device for heating the fresh air supplied via the first fresh air supply line.

The burner device may include a catalytic burner.

According to a preferred embodiment of the invention, the burner device contains a burner formed by a foam structure.

The catalytic burner can be formed by a catalytic coating formed on the foam structure.

The heating device is preferably an electrical heating device which is formed by a structure of an electrically conductive foam material.

The catalytic burner can advantageously be provided in the form of a catalytic coating on the foam structure of the heating device.

The foam structure can consist of stainless steel, preferably FeCrAlY, of steel or of a conductive ceramic.

Furthermore, the invention provides a method for operating a fuel cell arrangement of the type mentioned above. According to the invention, it is provided that the quantities of the fuel that are fed through the first fresh air supply line Fresh air supplied to the device is set such that a temperature between 750 ° C. and 1,400 ° C., preferably between 850 ° C. and 1,250 ° C., is established in the burner device during the afterburning of the combustible residual components contained in the used fuel gas.

According to a preferred embodiment of the method according to the invention, the entire flow of the used fuel gas is returned to the burner device via the anode gas return line.

According to a further preferred embodiment of the method according to the invention, the entire stream of the cathode exhaust gas which is returned via the cathode exhaust gas return line is returned to the burner device.

According to an alternative embodiment of the method according to the invention, a part of the flow of the cathode exhaust gas recirculated via the cathode exhaust gas return line is returned to the burner device and a part is returned to the cathode inlet.

According to one embodiment of the method according to the invention, the flows of the used fuel gas and the cathode exhaust gas can be passed through the burner device without further addition of fresh air.

According to another embodiment of the method according to the invention, part of the fresh air supplied can be supplied to the burner device via the first fresh air supply line.

Finally, it can be provided according to one embodiment of the method according to the invention that the entire Current of the cathode exhaust gas returned via the cathode exhaust gas return line is returned to the cathode inlet bypassing the burner device, and that the fresh air flow is fed exclusively via the first fresh air supply line to the burner device or partly via the first fresh air supply line to the burner device and partly via the second fresh air supply line bypassing the burner device to the cathode input is fed.

An exemplary embodiment of the fuel cell arrangement according to the invention and various variants of the method for operating such are explained below with reference to the figure.

The figure shows a block diagram of a fuel cell arrangement according to an embodiment of the invention.

The figure shows a schematic block diagram of a fuel cell arrangement. This typically contains a number of fuel cells arranged in the form of a fuel cell stack, of which only a single fuel cell 22 is shown in the figure for the sake of clarity.

The fuel cell 22 contains an anode 1 and a cathode 2 between which an electrolyte matrix, not shown in the figure, is arranged. The anode has an anode input AI for supplying fresh fuel gas (anode gas) and an anode output AO for removing the used fuel gas from the anode 1. Likewise, the cathode 2 has a cathode input KI for supplying fresh cathode gas and a cathode output KO for Removing the used cathode gas from the cathode 2. The fresh fuel gas is fed to the anode input AI from a pre-reforming device 20 via a heat exchanger 3. The used cathode gas is released from the cathode outlet KO via the heat exchanger 3, where it transfers its waste heat to the fresh fuel gas, to an exhaust gas discharge line 12. The cathode inlet KI is supplied with fresh air as cathode gas via a cathode inlet line 15 from a fresh air supply 18, 19 which contains a first fresh air supply line 18 and a second fresh air supply line 19.

An anode exhaust gas recirculation line 17 is provided between the anode outlet AO and the cathode inlet KI, into which a burner device 16 is connected. The burner device 16 serves for the post-combustion of combustible residual components contained in the used fuel gas.

The anode exhaust gas recirculation line 17 merges at the input of the burner device 16 with the first fresh air supply line 18, via which fresh air, which is conveyed by a circulating fan 9 and whose quantity can be adjusted by a fresh air control valve 10, can optionally be supplied to the burner device 16. The second fresh air supply line 19 serves to supply fresh air, which is conveyed by a blower 8 and the amount of which can be adjusted by a fresh air control valve 11, bypassing the burner device 16 directly to the cathode inlet line 15 or to the cathode inlet KI.

A cathode exhaust gas return line 6 is coupled from a point on the cathode exhaust line 12 downstream of the heat exchanger 3 to the first fresh air supply line 18 on the one hand and to the second fresh air supply line 19 via a control valve 7 on the other hand. The cathode exhaust gas recirculation line 6 serves to recirculate at least one part of the cathode exhaust gas in the exhaust line 12 via the first fresh air supply line 18 to the burner device 16 or via the control valve 7 and the second fresh air supply line 19 directly to the cathode inlet line 15 or the cathode inlet KI. The cathode exhaust gas flow which is returned via the cathode exhaust gas return line 6 can be recycled regardless of the amount of the fresh air supply line 18 and the second fresh air supply line 19, ie also when the fresh air control valve 10 and / or the fresh air control valve 11 are closed.

The burner device 16 contains a burner 4 for burning the combustible residual constituents contained in the anode exhaust gas and a heating device 5 for heating the fresh air supplied via the first fresh air supply line 18 together with the anode exhaust gas, optionally also only the supplied fresh air, in particular when starting up the fuel cell arrangement.

The burner 4 contained in the burner device 16 can contain a catalyst material and is preferably formed by a foam structure. The catalyst material can be provided by a catalytic coating formed on the foam structure.

The electrical heating device 5 is preferably an electrical heating device, which can be formed in particular by the structure of the foam material of the burner 4, in which case an electrically conductive foam material is provided. The catalytic coating can in particular be provided on the foam structure of the heating device 5, so that the burner 4 and the heating device 5 can be provided in a common element. The foam structure can especially made of stainless steel, preferably FeCrAlY, steel or a conductive ceramic.

The quantities of the fresh air supplied via the first fresh air supply line 18 to the burner device 16 are adjusted, taking into account the quantity of the anode exhaust gas returned from the anode outlet AO to the burner device 16 via the anode exhaust gas return line 17, such that the combustible residual constituents contained in the used fuel gas in the afterburning the burner device 16 sets a temperature between 750 ° C. and 1,400 ° C., preferably between 850 ° C. and 1,250 ° C.

Preferably, as in the case of the exemplary embodiment shown in the figure, the entire flow of the used fuel gas is returned from the anode outlet AO via the anode exhaust gas return line 17 to the burner device 16.

As for the flow of the cathode exhaust gas recirculated via the cathode exhaust gas recirculation line 6, either the entire amount of the cathode exhaust gas recirculated via the cathode exhaust gas recirculation line 6 can be supplied to the burner device 16 or a part can be returned to the burner device 16 and a part can be returned via the control valve 7 below

Bypassing the burner device 16 are fed directly to the cathode input KI. Provision can also be made for the entire flow of the cathode exhaust gas recirculated via the cathode gas return line 6 to be fed directly to the cathode inlet line 15 or the cathode inlet KI, bypassing the burner device 16.

The flows of the spent fuel gas returned from the anode outlet AO via the anode exhaust gas return line 17 and the used cathode exhaust gas returned via the cathode exhaust gas return line 6 can be passed through the burner device 16 without further addition of fresh air, ie with the fresh air control valve 10 closed. Alternatively, part of the fresh air can be fed to the burner device 16 via the first fresh air supply line 18 together with the recirculated anode exhaust gas and the recirculated cathode exhaust gas, and part of the fresh air can be fed directly to the cathode inlet line 15 or the cathode inlet KI bypassing the burner device 16 be fed. Finally, it can be provided that the entire flow of the cathode exhaust gas recirculated via the cathode gas return line 6 is bypassed the burner device 16, namely via the control valve 7 and the second fresh air supply line 19, directly to the cathode inlet line 15 or the cathode inlet KI, and that the fresh air flow a ) is supplied exclusively via the first fresh air supply line 18 and via the burner device 16 or b) partly via the first fresh air supply line 18 and via the burner device 16 and partly via the second fresh air supply line 19, bypassing the burner device 16 directly to the cathode inlet line 15 or the cathode inlet AI is supplied.

There is thus the possibility of freely varying the combustion conditions in the burner device 16 over a very wide range both over the size of the returned cathode exhaust gas flow and over the size of the fresh air flow supplied to the burner device 16 and thus realizing optimal combustion conditions in the burner device 16. For the burner 4 contained in the burner device 16, this means that less noble catalytic converter ren can be used or that the use of catalysts can be completely dispensed with.

LIST OF REFERENCE NUMBERS

Anode cathode heat exchanger burner heater cathode exhaust gas return line control valve blower circulation blower fresh air control valve fresh air control valve exhaust gas discharge mixed gas return line fresh air line cathode inlet line burner device anode exhaust gas return line first fresh air supply line second fresh air supply line pre-reforming device

Claims

claims

1. Fuel cell arrangement with one or more fuel cells, each containing an anode (1) and a cathode (2), with an anode input (AI) for supplying fresh fuel gas to the anodes (1) and an anode output (AO) for removing used fuel gas from the anodes (1), with a cathode inlet (KI) for supplying fresh cathode gas to the cathodes (2) and a cathode outlet (KO) for discharging used cathode gas from the cathodes (2), with a fresh air supply (18, 19) for supplying fresh air to the cathode inlet (KI) and with a burner device (16) connected via an anode exhaust gas recirculation line (17) between the anode outlet (AO) and the cathode inlet (KI) for afterburning of the spent in the anode outlet (AO) Combustible residual components containing fuel gas, optionally together with fresh air supplied via the fresh air supply (18, 19), characterized in that the Fresh air supply (18, 19) a first fresh air supply line (18) connected to the burner device (16) for optionally supplying fresh air together with the used fuel gas to the burner device (16) and a second fresh air supply line (19) for supplying fresh air to the cathode inlet (KI ) bypassing the burner device (16).

2. Fuel cell arrangement according to claim 1, characterized in that control devices (10, 11) for setting the first fresh air supply line (18) and over the second fresh air supply line (19) supplied fresh air quantities are provided.

3. Fuel cell arrangement according to claim 1 or 2, characterized in that in the first fresh air supply line (18) or the second fresh air supply line (19) respective blowers (8, 9) are provided for conveying adjustable amounts of fresh air.

4. Fuel cell arrangement according to claim 1, 2 or 3, characterized in that between the cathode outlet (KO) and the burner device (16) and / or the cathode inlet (KI) coupled cathode exhaust gas return line (6) for returning at least part of the cathode exhaust gas the burner device (16) and / or the cathode input (KI) is provided.

5. Fuel cell arrangement according to claim 4, characterized in that the cathode exhaust gas return line (6) for returning part of the cathode exhaust gas with the burner device (16) and for returning part of the cathode exhaust gas to the cathode inlet (KI), preferably via the second fresh air supply line (19), is coupled to the cathode input, a control valve (7) for setting the ratio of the amounts of cathode exhaust gas returned to the burner device (16) or to the cathode input (KI) preferably being provided.

6. Fuel cell arrangement according to one of claims 1 to 5, characterized in that the burner device (16) a burner (4) for burning the combustible residual constituents contained in the anode exhaust gas and a heating device (5) for heating the fresh air supply line (18) supplied Contains fresh air.

7. Fuel cell arrangement according to one of claims 1 to

6, characterized in that the burner device (16) contains a catalytic burner.

8. Fuel cell arrangement according to one of claims 1 to

7, characterized in that the burner device (16) contains a burner (4) formed by a foam structure.

9. Fuel cell arrangement according to claim 7 in conjunction with claim 8, characterized in that the catalytic burner (4) is formed by a catalytic coating formed on the foam structure.

10. Fuel cell arrangement according to claim 6 in connection with claim 8 or 9, characterized in that the heating device (5) is an electrical heating device which is formed by a structure of an electrically conductive foam material.

11. Fuel cell arrangement according to claim 9 in conjunction with claim 10, characterized in that the catalytic coating is provided on the foam structure of the heating device (5).

12. Fuel cell arrangement according to claim 10 or 11, characterized in that the foam structure made of stainless steel, preferably FeCrAlY, made of steel or a conductive ceramic.

13. The method for operating a fuel cell arrangement according to one of claims 1 to 12, characterized in that the amount of fresh air supplied via the first fresh air supply line (18) to the burner device (16) it is set that a temperature between 750 ° C. and 1,400 ° C., preferably between 850 ° C. and 1,250 ° C., arises in the burner device (16) during the afterburning of the combustible residual components contained in the used fuel gas.

14. The method according to claim 13, characterized in that the entire flow of the used fuel gas is returned via the anode exhaust gas return line (17) to the burner device (16).

15. The method according to claim 13 or 14 for operating a fuel cell arrangement according to one of claims 4 to 12, characterized in that the entire flow of the cathode exhaust gas returned via the cathode exhaust gas return line (6) is returned to the burner device (16).

16. The method according to claim 13 or 14 for operating a fuel cell arrangement according to one of claims 5 to 12, characterized in that part of the current of the cathode exhaust gas returned via the cathode exhaust gas return line (6) is returned to the burner device (16) and part is returned to the cathode entrance (KI).

17. The method according to claim 15 or 16, characterized in that the flows of the used fuel gas and the cathode exhaust gas are passed through the burner device (16) without further addition of fresh air.

18. The method according to any one of claims 13 to 16, characterized in that a part of the fresh air supplied via the first fresh air supply line (18) is fed to the burner device (16).

19. The method according to claim 13 or 14 for operating a fuel cell arrangement according to one of claims 5 to 12, characterized in that the entire flow of the cathode exhaust gas returned via the cathode exhaust gas return line (6) bypassing the burner device (16) to the cathode inlet (KI ) is fed back, and that the fresh air flow via the first fresh air supply line (18) is fed exclusively to the burner device (16) or partly via the first fresh air supply line (18) to the burner device (16) and partly via the second

Fresh air supply line (19) bypassing the burner device (16) is fed to the cathode inlet (KI).