DE102012219141A1 - Chromium-resistant fuel cell system and method of operating the same - Google Patents

Abstract

A fuel cell system is described with a fuel cell unit (12) comprising at least one anode (46) and one cathode (42) which are in electrical contact with one another via an electrolyte (16a-16d, 40, 52a-52c), the anode (46) with a fuel gas and the cathode (42) with an oxygen-containing gas, in particular air, through air-carrying components (18, 22) of the fuel cell system (10). At least in the area of the air-carrying components (18, 22), a chromium compound absorbing or adsorbing material (24) is provided which is in contact with the oxygen-containing gas mixture supplied to the cathode (42).

Description

The present invention relates to a fuel cell system and a method of operating the same according to the preamble of the independent claims.

State of the art

High-temperature fuel cells, such as solid oxide fuel cells (SOFC) have in a preferred embodiment, tubular, oxide ceramic fuel cell units, which may be open, for example open on both sides, so that fuel gas can be passed through the tubular fuel cell unit. Alternatively, such fuel cell units can also be designed to be closed on one end side, in which case the fuel gas is preferably introduced into the interior of the fuel cell tube via a lance. The outside of each fuel cell tube is lapped with air. Preferably, the oxide-ceramic tube acts as a solid electrolyte and is coated on its inside with a layered anode and on its outside with a layered cathode. Such an embodiment is for example the DE 10 2010 001 988 refer to.

Due to the high operating temperature of SOFC fuel cell systems, the SOFC fuel cell stack is preferably in its own housing, the so-called "hot box". The SOFC fuel cell stack is preferably charged with preheated air having a temperature> 620 ° C. To ensure the warming of the air, this is passed, for example, through chromium-containing steel pipes or chromium-containing heat exchangers and then fed to the SOFC fuel cell stack. When passing chromium-containing steel pipes or chromium-containing heat exchanger takes the air to be heated depending on temperature and humidity on chromium compounds, which it emits, for example, within the SOFC fuel cell stack to the material of the cathode placed there again. This results in poisoning of the cathodes of the SOFC fuel cell stack. As a result, there is a degradation of the SOFC fuel cell stack and thus associated with a performance penalty.

To remedy this problem, it is for example from the JP 2008-147086 A known to charge negative chromium vapors to prevent chromium poisoning of a fuel cell stack and then intercept in a arranged at a stack input chrome trap using appropriate electrical fields. However, this solution is associated with a certain technical effort.

Furthermore, the US 2005/0142398 A1 to avoid chromium-induced cathode poisoning in fuel cells in that feed gases for the cathode region of the fuel cell are kept continuously at an extremely low level of moisture. This is achieved both physically and chemically. This solution is technically complex.

It is therefore an object of the present invention to provide a fuel cell system or a method for operating the same in which chromium poisoning of cathodes of a fuel cell stack can be successfully avoided and thus degradation of the fuel cell stack is prevented.

Disclosure of the invention

The problem underlying the invention is achieved by a fuel cell system or by a method for operating the same with the characterizing features of the independent claims in an advantageous manner.

This is based in particular on the fact that at least in a region of the fuel cell system in which a cathode of the fuel cell system is supplied with an oxygen-containing gas such as air, a material is provided which absorbs or adsorbs chromium compounds entrained in the oxygen-containing gas stream. In this way, chromium compounds are removed from the cathode to be supplied oxygen-containing gas mixture before it can come into contact with the cathode of the fuel cell system. This allows prevention of chromium poisoning of the cathode of the fuel cell system in a technically simple yet effective way.

Further advantageous embodiments of the present invention are the subject of the dependent claims.

It is advantageous if the chromium-absorbing material is part of a sacrificial cathode which is positioned in the air inlet region of the fuel cell and connected to an anode in such a way that a corresponding negative potential of, for example, 750 mV is applied to the sacrificial cathode.

In this case, the sacrificial cathode or the electrical cell, whose component is the sacrificial cathode, preferably not used for the provision of electrical power by the fuel cell system, otherwise in degradation of the sacrificial cathode a performance limitation of the fuel cell system would be the result. In this way, the sacrificial cathode serves to remove chromium-containing compounds from an oxygen-containing gas mixture to be supplied to the fuel cell, without their degradation leading to a power loss of the fuel cell.

Furthermore, it is advantageous if the chromium-absorbing material corresponds to a material which is also part of the cathodes of the fuel cell system. These may be, for example, (La, Sr) MnO ₃ (LSM) or (La, Sr) (Co, Fe) O ₃ (LSCF). In this way, it is ensured that chromium-containing compounds which are supplied with an oxygen-containing gas stream of the fuel cell are bound to the extent in the region of the chromium-absorbing material, as they would be bonded to surfaces of the cathode of the fuel cell unit.

According to a particularly advantageous embodiment of the present invention, in the case of a fuel cell unit designed in tubular form, at least one tube is occupied by the chromium-absorbing material, in particular on the outside thereof, instead of with a fuel cell cathode. This offers the advantage that, with an almost unchanged design of the fuel cell, elimination of compounds containing chromium in an oxygen-containing gas mixture supplied to the fuel cell unit can be effected.

According to a further particularly advantageous embodiment, the chromium-absorbing material is positioned in the form of an exchangeable unit within the fuel cell system or in particular within a fuel cell unit of the fuel cell system. This makes it possible to exchange the chromium-absorbing material, which acts as a so-called getter, without having to replace the fuel cell unit per se.

In order to monitor the absorption capacity of the chromium-absorbing material, it is checked, for example in a suitable manner, preferably continuously for its further absorption capacity for chromium-containing compounds. This can be done, for example, by switching the chromium-absorbing material as a cathode and monitoring its cathodic potential. If this deviates from an original value beyond a predetermined threshold value, it is concluded that chromium-containing compounds are at least largely occupied by the chromium-absorbing material and, for example, an exchange of the chromium-absorbing material is initiated. This embodiment contributes in a technically simple manner to a high reliability of the fuel cell unit.

embodiments

The invention will be explained in more detail with reference to the drawings and the description below. It shows:

1 1 is a schematic cross section of a fuel cell unit of a fuel cell system according to a first embodiment of the present invention;

2 12 is a schematic cross section of a fuel cell unit of a fuel cell system according to a second embodiment of the present invention;

3 a schematic longitudinal section of a fuel cell unit of a fuel cell system according to a third embodiment of the present invention

4 a schematic longitudinal section of a fuel cell unit of a fuel cell system according to a fourth embodiment of the present invention and

5 a schematic cross section of a fuel cell unit of a fuel cell system according to a fifth embodiment of the present invention.

Description of the embodiments

The in the 1 to 4 Unless stated otherwise, reference symbols used always refer to functionally identical structural or system components.

In 1 is a fuel cell system 10 according to a first embodiment of the present invention. This includes a fuel cell unit 12 , which in turn comprises a plurality of individual fuel cells, of which, by way of example, the fuel cells 14a - 14d marked with reference numerals. The fuel cells 14a - 14d For example, they are designed in the form of high-temperature fuel cells (SOFC), which have a cylindrical, one-sided closed ceramic tube 16a - 16d include. The tube 16a - 16d acts as a solid electrolyte, on the surface thereof, not shown anodes or cathodes of the individual fuel cells 14a - 14d are applied.

In addition, the fuel cell unit includes 12 an air inlet 18 as well as an air outlet 20 , About the air intake 18 will the fuel cell unit 12 supplied with air, which preferably the outer surfaces of the tube 16a - 16d exported executed ceramic electrolytes. These are in turn with cathode, not shown, of the individual fuel cells 14a - 14d busy. The air is finally over the air outlet 20 from the fuel cell unit 12 dissipated.

To prevent chromium containing compounds from entering via the air inlet 18 supplied air into the interior of the fuel cell unit 12 and thus in contact with the cathodes of the individual fuel cells 14a - 14d can reach, is preferably in the direction of flow of air to the fuel cell 14a - 14d upstream, for example, in an air intake area 22 the fuel cell unit 12 a means 24 intended to absorb chromium-containing compounds.

According to the in 1 illustrated embodiment is the means 24 for absorption of chromium-containing compounds, for example as a coating on a wall of the air inlet area 22 the fuel cell unit 12 executed. This coating contains a substance capable of absorbing chromium-containing compounds. This substance may, for example, be a so-called getter material which is opposite in the fuel cell unit 12 supplied chromium compounds is chemically reactive and binds them. These may be, for example, (La, Sr) (Co, Fe) O ₃ (LSCF), (La, Sr) CoO ₃ (LSC), a lanthanum strontium ferrite (LSF) or (La, Sr) MnO ₃ (LSM) act.

According to an alternative embodiment, the means 24 connected to the absorption of chromium-containing compounds as the cathode of an electrochemical cell and acts in particular when the agent 24 In addition, for the absorption of chromium-containing compounds contains at least one material, as well as for the cathodes of the corresponding fuel cells 14a - 14d is used as a sacrificial cathode.

This effect is based on the fact that the means implemented as a sacrificial cathode 24 for absorption of chromium-containing compounds even before the cathodes of the fuel cells 14a - 14d the air supplied, which optionally contains chromium-containing compounds, is exposed and thus poisoning of the sacrificial cathode occurs, causing poisoning of the cathode of the fuel cell 14a - 14d at least largely avoided.

Further alternative embodiments of this embodiment provide that the means 24 Chromium-containing compounds not as a layer in the air inlet area 22 the fuel cell unit 12 is executed, but that, for example, the air inlet area 22 the fuel cell unit 12 at least partially or wholly made of a material for absorption of chromium-containing compounds and thus as an agent 24 acts to absorb chromium-containing compounds.

Alternatively or additionally, air-carrying components of the fuel cell system can also be used 10 , the supply of air to the fuel cell unit 12 serve, be wholly or partly of a chromium compounds absorb material or be coated with such a material and thus as an agent 24 be used for the absorption of chromium-containing compounds.

A fuel cell system 10 according to a second embodiment of the present invention is in 2 shown. In this case, the air inlet area includes 22 the fuel cell unit 12 as a means 24 For absorption of chromium-containing compounds, for example, more fuel cells 14e - 14h , which are operated as electrochemical cells and their cathodes due to the positioning of the other fuel cells 14e - 14h in the air intake area 22 the fuel cell unit 12 act as sacrificial cathodes. Alternatively, it is also possible, the other fuel cells 14e - 14h also statistically distributed within the fuel cell unit 12 to arrange.

Here are advantageously as the chromium compounds absorbing substance of the agent 24 For the absorption of chromium-containing compounds substances or materials used, as they are also commonly used for cathode of corresponding fuel cells or high-temperature fuel cells. In the case of high-temperature fuel cells SOFC, these are, for example, (La, Sr) MnO ₃ (LSM) or (La, Sr) (Co, Fe) O ₃ (LSCF).

Another embodiment of a fuel cell system according to the present invention is 3 refer to.

In this case, the fuel cell unit 12 further fuel cell units 14i . 14j on. The other fuel cells 14i . 14j each contain an electrolyte body 40 in terms of its geometric configuration, the mechanical structure of the fuel cell 14i . 14j pretends. The electrolyte body 40 has a wall thickness that provides sufficient rigidity of the fuel cell 14i . 14j causes. It is embodied, for example, from a corresponding ceramic material which, for example, partially or fully stabilized zirconium dioxide, is suitable for use in high-temperature fuel cells.

On the electrolyte body 40 are applied inside and outside electrodes. So inside is a first electrode material 46 provided, which forms an anode, and on the outside a second electrode material 42 which represents a cathode.

The fuel cell unit shown 12 FIG. 12 illustrates only one embodiment of the present invention, the features of the present invention also being applied to fuel cells configured as anode and cathode based SOFC fuel cells, respectively. In this case, the anode or cathode material itself is formed as a stiffened body, which causes the mechanical structure of the fuel cell. Another alternative is that the SOFC fuel cells are carried inert supported.

The electrolyte body 40 is designed as a closed end body, with a cap 48 is provided, which is the free end of the electrolyte body 40 , which is a flange section 44 is arranged opposite, closes.

The fuel cell 14i . 14j can be operated with a fuel gas, preferably with hydrogen, via a feed channel 47 first in a basic body 45 the fuel cell unit 12 and then in a lance 43 arrives. Through the lance 43 the fuel gas is up to the free end of the electrolyte body 40 headed and steps out of the lance 43 out. The end of the lance 43 leaking fuel gas subsequently flows around the inner first electrode material 46 , On the outside, the second electrode material acting as the cathode becomes 42 lapped in a manner not shown in detail with air.

To poison the cathodes of fuel cells 14i . 14j For example, at least part of the cathodes is subdivided into two compartments, for example, separated from one another by insulating layers 45 are electrically separated, with an example of the fuel cell unit 12 supplied air most exposed area of the cathode as a sacrificial cathode and thus as a means 24 designed to absorb chromium-containing compounds. In this case, as the sacrificial cathode, for example, the closed end of serving as the electrolyte tube 40 facing part of the second electrode material 42 as a means 24 However, alternatively or additionally, other areas of the cathode of the fuel cell can be designed for absorption of chromium-containing compounds 14i . 14j as a means 24 be carried out for the absorption of chromium-containing compounds. In this case, it is advisable to contact the cathodes, which are designed as sacrificial cathodes, separately electrically and to interconnect in each case to form an electrochemical cell. This may be, for example, with respect to the cathodes of the fuel cells 14i . 14j have deviating, in particular negative potential.

Another embodiment of a fuel cell system according to the present invention is shown in FIG 4 shown.

In this case, the fuel cell unit 12 also other fuel cell units 14i . 14j on. The other fuel cells 14i . 14j contain as carrier each an inert ceramic body 41 in terms of its geometric configuration, the mechanical structure of the fuel cell 14i . 14j pretends. The inert ceramic body 41 has in this case a wall thickness, which has a sufficient rigidity of the fuel cell 14i . 14j causes. It is, for example, made of a corresponding ceramic material such as, for example, aluminum oxide.

On the inert ceramic body 41 On the inside electrodes are applied. So inside is a first electrode material 46 provided, which forms an anode, and a second electrode material 42 which represents a cathode. Between the first and the second electrode material 42 . 46 is preferably an electrolyte layer, which functions in the electrolyte body 40 of the embodiment according to 3 equivalent. The from the first electrode material 46 , the electrolyte body 40 and the second electrode material 42 The layer sequence formed is preferably on the inside and thus on the side exposed to the fuel gas of the inert, ceramic body 41 positioned that the second, the cathode forming electrode material 42 flat on the surface of the inert, ceramic body 41 is arranged.

The inert ceramic body 41 is designed as a closed end body, with a cap 48 is provided, which is the free end of the electrolyte body 40 , which is a flange section 44 is arranged opposite, closes.

The fuel cell 14i . 14j can be operated with a fuel gas, preferably with hydrogen, via a feed channel 47 first in a basic body 45 the fuel cell unit 12 and then in a lance 43 arrives. Through the lance 43 the fuel gas will reach the free end of the inert ceramic body 41 headed and steps out of the lance 43 out. The end of the lance 43 leaking fuel gas subsequently flows around the inner first electrode material 46 ,

To poison the cathodes of fuel cells 14i . 14j to prevent is on the outside of the inert ceramic body exposed to the supplied air 41 for example, a porous cathode as an agent 24 intended to absorb chromium-containing compounds and serves as a sacrificial cathode. This is electrically contacted separately and connected in each case to form an electrochemical cell. These For example, with respect to the cathodes of the fuel cells 14i . 14j have deviating, in particular negative potential.

A fifth embodiment of a fuel cell system according to the present invention is shown in FIG 5 shown.

The fuel cell unit 12 includes an electrolyte membrane 52a . 52b . 52c at least partially on a first large area, for example, the inside of a through the electrolyte membrane 52 forms formed tube, with the acting as an anode, preferably flat first electrode material 46 is coated.

Furthermore, the electrolyte membrane 52a . 52b . 52c preferably on its first large area opposite the second large area, for example, through the outside of the running in the form of a tube electrolyte membrane 52a . 52b . 52c is formed, with the second electrode material functioning as a cathode 42 at least partially coated.

In this case, the electrolyte membrane forms 52a . 52b . 52c the supporting structure of the fuel cell unit 12 , As the electrolyte membrane 52a . 52b . 52c Furthermore, it is preferably wavy in shape at least in regions, it is possible, for example by means of suitable interconnectors 54 each in the interior of the through the electrolyte membrane 52a . 52b . 52c formed tubus facing portions of the electrolyte membrane 52a . 52b . 52c with further, these inwardly facing areas opposite, also inwardly facing other areas of the electrolyte membrane 52a . 52b . 52c so connect that out of the electrolyte membrane 52a . 52b . 52c formed tube is subdivided into further, spatially separated subunits, which in turn each a closed gas space 58a . 58b . 58c . 58d form in the form of a tube. Alternatively, instead of a wavelike basic structure of the electrolyte membrane 52a . 52b . 52c also a honeycomb basic structure can be selected.

In this way, a composite of several gas chambers 58a . 58b . 58c . 58d whose interior is in contact with a first electrode material functioning as a common anode 46 stands. In operation, for example, the inner gas spaces 58a . 58b . 58c . 58d with an oxidizable, preferably gaseous fluid such as hydrogen, methane or gaseous methanol. At the same time, for example, the outer surface of the electrode material acting with the second, acting as a cathode 42 provided electrolyte membrane 52a . 52b . 52c contacted with a preferably gaseous oxidizing agent such as air or pure oxygen, in corresponding second gas spaces 54a . 54b . 54c . 54d to be led.

This results in an electrochemical conversion of the in the inner gas spaces 58a . 58b . 58c . 58d guided oxidizable fluid to release an electric current flow between the first and the second electrode material 46 . 42 which can be tapped and used by suitable external peripherals.

To a poisoning of the cathode of the fuel cell unit 12 acting second electrode material 42 to prevent are the second gas spaces acted upon with air 54a . 54b . 54c . 54d For example, in their air inlet side area with a means not shown here 24 occupied for the absorption of chromium-containing compounds. This can, as already described above, take place in the form of a coating by a getter material for chromium compounds or by the formation of a corresponding sacrificial cathode.

To a long running time of the fuel cell system 10 to ensure that is the means 24 for absorption of chromium-containing compounds, for example, as an exchangeable unit, and thus reversible with the fuel cell system 10 connected running. In this way, after an occupancy of the agent 24 for the absorption of chromium-containing compounds with chromium or chromium compounds this exchanged and replaced by an unspent embodiment. For example, the air intake area 22 the fuel cell unit 12 as an exchangeable element reversible with the fuel cell unit 12 and / or with the air supply 18 and together with the means positioned therein 24 If necessary, they can be exchanged for the absorption of chromium-containing compounds. The same applies if, for example, the air inlet area 22 the fuel cell unit 12 or the air supply 18 itself is formed by a material which absorbs chromium-containing compounds from the supplied air and thus as an agent 24 designed to absorb chromium-containing compounds.

To recognize the point in time at which the means 24 For absorption of chromium-containing compounds with chromium-containing compounds is at least largely saturated, a corresponding sensor, for example, in the air-bearing system of the fuel cell system 10 the means 24 be positioned downstream of the absorption of chromium-containing compounds, for example, detects the concentration of chromium-containing compounds in a flowing past the sensor gas mixture. As a sensor, for example, a switched as a sacrificial cathode means 24 for the absorption of chromium Connections are used in the context of the present application, wherein the potential of the sacrificial cathode is monitored, and closed in case of deviation of the potential on an occupancy of the sacrificial cathode of the sensor with chromium-containing compounds and the exchange of the agent 24 for the absorption of chromium-containing compounds is caused.

Fuel cell systems according to the present invention can be advantageously used in applications for high-temperature fuel cells SOFC such as in cogeneration plants or in power plants for power generation.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010001988 [0002]
• JP 2008-147086 A [0004]
• US 2005/0142398 A1 [0005]

Claims (12)

Fuel cell system, in particular high-temperature fuel cell system, with a fuel cell unit ( 12 ) comprising at least one anode ( 46 ) and a cathode ( 42 ), which have an electrolyte ( 16a - 16d . 40 . 52a - 52c ) are in electrical contact with each other, the anode ( 46 ) is acted upon by a fuel gas and the cathode ( 42 ) with an oxygen-containing gas, in particular air, via air-carrying components ( 18 . 22 ) of the fuel cell system ( 10 ) is acted upon, characterized in that at least in the region of the air-conducting components ( 18 . 22 ) a chromium compounds absorbing or adsorbing material ( 24 ) which is in contact with the cathode ( 42 ) is supplied oxygen-containing gas mixture. Fuel cell system according to claim 1, characterized in that the chromium compounds absorbing or adsorbing material ( 24 ) Part of a in the air intake area ( 22 ) of the fuel cell unit ( 12 ) is positioned sacrificial cathode. Fuel cell system according to claim 2, characterized in that the sacrificial cathode with an anode forms an electrical cell, which does not or only insignificantly in the provision of electrical power by the fuel cell system ( 10 ) is involved. Fuel cell system according to one of the preceding claims, characterized in that as chromium compounds absorbing or adsorbing material ( 24 ) a material of the cathode ( 42 ) of the fuel cell system ( 10 ) is used. Fuel cell system according to claim 4, characterized in that the chromium absorbing or adsorbing material ( 24 ) is a (La, Sr) MnO ₃ or a (La, Sr) (Co, Fe) O ₃ . Fuel cell system according to one of the preceding claims, characterized in that one with the fuel cell unit ( 12 ) connected supply line ( 18 ) for the supply of the oxygen-containing gas to the fuel cell unit ( 12 ) and / or the air intake area ( 22 ) of the fuel cell unit ( 12 ) for the oxygen-containing gas at least partly from the chromium absorbing or adsorbing material ( 24 ) is made. Fuel cell system according to one of the preceding claims, characterized in that fuel cells ( 14a - 14j ) of the fuel cell unit ( 12 ) are in tubular form and that at least one tube ( 16a . 16b . 40 . 58a - 58d ) on its outside with the chromium absorbing or adsorbing material ( 24 ) is occupied. Fuel cell system according to one of the preceding claims, characterized in that the chromium absorbing or adsorbing material ( 24 ) in the flow direction of the fuel cell unit ( 12 ) supplied oxygen-containing gas mixture upstream of the fuel cell unit ( 12 ) is positioned. Method for operating a fuel cell system according to one of the preceding claims, characterized in that a monitoring of the capacity of a chromium-absorbing material ( 24 ), which in the area of the air-conducting components ( 18 . 22 ) of the fuel cell system ( 10 ) with respect to further absorption or adsorption of chromium or chromium-containing compounds. Process according to claim 9, characterized in that the chromium absorbing or adsorbing material ( 24 ) is switched as a cathode and that when changing the cathode potential of this cathode beyond a predetermined threshold addition to an occupancy of the chromium absorbing or adsorbing material ( 24 ) is closed with chromium-containing compounds. A method according to claim 9 or 10, characterized in that the chromium absorbing or adsorbing material as a replaceable unit within the fuel cell system ( 10 ) is arranged. Use of a fuel cell system according to one of claims 1 to 8 in combined heat and power plants and / or SOFC stacks.

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