DE102014207142A1 - Method for operating a fuel cell system and apparatus for carrying out the method - Google Patents

Abstract

The invention relates to a method for operating a fuel cell system. The fuel cell system includes at least one fuel cell having a cathode and an anode, the cathode being connected to a cathode gas supply. To an output of the fuel cell, a fuel cell exhaust pipe is connected. The fuel cell exhaust line comprises at least a first condenser, which contains at least one heat exchanger and at least one water separator, wherein the anode is connected via a hydrogen supply with a hydrogen storage. The method is characterized by the step of transferring heat from the fuel cell exhaust air to the hydrogen to be supplied to the anode while condensing water from the fuel cell exhaust air in the first condenser.

Description

The present invention relates to a method for operating a fuel cell system, to an apparatus for carrying out the method and to a motor vehicle comprising such a device.

The hydrogen taken from cryogenic tanks, so-called cryotanks, for fuel cell systems, which is used as anode gas for operating fuel cells, must be heated in order to prevent damage to the fuel cell system due to the low temperatures and to provide a sufficiently high performance of the fuel cell system. The heating takes place for example by a heating device. In order to heat the up to about -255 ° C cold hydrogen to working temperature, the heater consumes a large amount of energy. In addition, there are fuel cell systems that u. a. to avoid water vapor clouds in the exhaust gas and thus to prevent the risk of the formation of ice surfaces in the vicinity of the exhaust outlet or for water injection (either for humidification of the fuel cell to be supplied cathode gas or for cooling the fuel cell system), a separation or even a recovery of water from the Provide cathode exhaust air. Usually, the recovery takes place by means of a capacitor which, however, can deposit or recover only a very small proportion of water, especially at high ambient temperatures, so that the power of the fuel cell system can not be fully utilized, especially in the summer months, without a significant share of further energy to spend sufficient water recovery for cooling the fuel cell system and for humidifying the cathode gas.

Based on this prior art, it is therefore an object of the present invention to provide a method for operating a fuel cell system, which promotes a balanced, economical energy management, and thus enables energy-efficient operation of the fuel cell system. Furthermore, it is an object of the present invention to provide an apparatus for carrying out the method for operating a fuel cell system with a hydrogen storage and a motor vehicle comprising such a device, which works energy-saving, avoids the formation of water condensation clouds in the fuel cell system exhaust air, and at the same time substantially without supplying heat from external heaters in the provision of anode hydrogen gas manages.

The object is achieved in a method for operating a fuel cell system comprising at least one fuel cell with a cathode and an anode. The cathode is for this purpose connected to a cathode gas supply. To an output of the fuel cell, a fuel cell exhaust pipe is further connected. Under a Brennstoffzellenabluftleitung in the context of the invention, a cathode exhaust passage, the exhaust gases of the cathode transported, an anode exhaust passage, the exhaust gases of the anode conveyed or a fuel cell Mischabluftuftleitung, which conveys a mixed exhaust gas from exhaust gases of the anode and the cathode understood. Accordingly, if a component in the fuel cell exhaust line is used in accordance with the invention, the component can be located in the cathode exhaust line, in the anode exhaust line or in the fuel cell mixed exhaust air line, as long as no restrictive details are given. According to the invention, at least one first condenser, which comprises at least one heat exchanger and at least one water separator, is arranged in the fuel cell exhaust line. The anode is connected via a hydrogen supply with a hydrogen storage. The method according to the invention is characterized by the step of transferring heat from the fuel cell exhaust air present in the fuel cell exhaust line to the hydrogen to be supplied to the anode while condensing water out of the fuel cell exhaust air in the first capacitor.

For the purposes of the invention, a hydrogen storage means any type of tank system in which the hydrogen to be supplied to the anode is stored at a temperature level which is at least 20 ° C. below the temperature of the exhaust air in the fuel cell exhaust line. Preferably, the hydrogen is stored in the hydrogen storage below about 0 ° C. The greater the temperature difference between the stored hydrogen and the exhaust air in the fuel cell exhaust line, the greater the effect achieved according to the invention. A hydrogen storage thus includes conventional cryogenic tanks, but the liquid hydrogen also store tanks, so-called Kryodrucktanks, which are approved for an operating temperature of -240 ° C to 85 ° C, in which the hydrogen is kept in gaseous pressure and at a corresponding temperature level. By transferring heat from the cooling of the fuel cell exhaust air and release of condensation heat to be provided to the anode hydrogen, two beneficial effects are achieved: on the one hand, the fuel cell exhaust heat is removed, so that it cools and condensed water in the condenser, the targeted can be discharged from the fuel cell exhaust air. On the other hand, this heat is directly related to the temperature increase of the anode-side hydrogen ready. Thus, the formation of condensation water clouds in the exhaust gas of the fuel cell system is effectively avoided and at the same time, in particular without supply of external energy, an increase in the temperature of the fuel gas of the fuel cell, preferably to a temperature which is at least as high as the dew point of the fuel cell exhaust air obtained. The more heat is transferred to the hydrogen, the higher power requests to the fuel cell system can be operated and the lower then the temperature of the fuel cell exhaust decreases, so that more water is condensed out of the fuel cell exhaust air. Optical impairments due to condensation clouds are thus effectively avoided and safety-relevant aspects due to ice formation, especially due to uncontrolled condensation of fuel cell exhaust water at low ambient temperatures, are taken into account. By the method according to the invention, the fuel cell system can be operated energy-saving, highly efficient and safe.

The dependent claims have advantageous developments and refinements of the invention to the content.

According to an advantageous development of the method according to the invention, the transfer of heat from the fuel cell exhaust air to the hydrogen in the hydrogen storage and / or to the hydrogen in the hydrogen supply takes place. Although the transfer of heat to the hydrogen in the hydrogen storage, so for example by heating the memory itself, initially requires a high input of heat energy, but ensures a reliable and durable power delivery of the fuel cell system. A transfer of heat to the hydrogen, which has already been taken from the hydrogen storage and is in the hydrogen supply line, is particularly advantageous when the fuel cell system is being started up, since at this time the fuel cell exhaust often only carries small amounts of water with it and the heat transfer can only be done on a smaller scale. The heat transfer is then compared to that of a water heater. Also possible is a combined heat transfer both to the hydrogen in the hydrogen storage and to the hydrogen in the hydrogen supply.

The transfer of heat to the anode-side hydrogen preferably takes place from the cathode exhaust air and / or the anode exhaust air. Since in particular the cathode exhaust air leads to larger amounts of water, a transfer of heat from the cathode exhaust air by condensation of water is particularly preferred.

In order to further increase the energy efficiency of the method according to the invention, the condensed water is fed to the cathode gas supply and / or the fuel cell. This can spare a separate wetting of the cathode gas and / or external cooling devices for the fuel cell. Due to the efficient water separation and the resulting humidification even high power requests to the fuel cell system can be operated, whereby even with the same generated electrical power less heat is produced, so that the cooling system is additionally relieved.

The transfer of heat takes place particularly efficiently by passing through a gas / gas heat exchanger or alternatively by passing through two liquid / gas heat exchangers connected in a fluid-conducting manner. A gas / gas heat exchanger is particularly space-saving.

Further advantageously, the transfer of heat is carried out according to the countercurrent principle, as this takes place the best possible heat transfer, at the same time high temperature gradients are avoided in the Brennstoffellenabluftleitung. High gradients can interfere with freezing water and expose the materials to unnecessary stress.

A further advantageous embodiment provides that the hydrogen is expanded before or after the transfer of heat. An expansion before the heat transfer has the advantage that the expansion of the hydrogen cools this further and the low pressure, the design of the heat exchanger of the first capacitor is easier. An expansion after the heat transfer is technically easier to implement because z. B. no pressure control valves are needed, which operate under cryogenic conditions. In return, the hydrogen in this case continues to heat up as a result of the expansion carried out (negative Joule-Thomson effect), as a result of which the heat to be transferred can be lower.

Further advantageously, the cold released during the expansion of the hydrogen is used to cool the cathode exhaust air and / or to condense water out of the cathode exhaust air. This allows for the same molar amount of hydrogen, an additional condensation of water, which is especially at high ambient temperatures for a sufficient condensation of water and thus a good humidification of the cathode gas and / or cooling of the fuel cell, an advantage.

Due to the advantageous development that the fuel cell system, a second capacitor and the method is characterized by the step of condensing water out of the fuel cell exhaust air in the second condenser, even lower temperatures are achieved in the fuel cell exhaust air so that a larger amount of water can be separated therefrom for cooling purposes and for humidifying cathode gas is available. The first capacitor and the second capacitor can be integrated in separate components or in one component. Preferably, both capacitors share a water separator, since thus the process is simplified.

Due to the advantageous step of storing condensed water in a water tank, retention of condensation water can take place, so that with high power requests to the fuel cell system can be targeted and reacted directly, without delay, with high cooling capacity and a sufficient amount of moistened cathode gas. In addition, it is possible to drain excess water at defined times, or in a portable fuel cell system at specific locations. This can be done for example via a separate outlet or via an exhaust system of the fuel cell system.

Furthermore, the present invention relates to an apparatus for carrying out the method described above. The device comprises at least one fuel cell having a cathode and an anode, wherein the cathode is connected to a cathode gas supply. The fuel cell further comprises at its output a fuel cell exhaust conduit comprising at least a first condenser containing at least one heat exchanger and at least one water separator. The anode is connected via a hydrogen supply with a hydrogen storage. According to the invention, the first capacitor is connected in a heat-conducting manner to the hydrogen storage and / or the hydrogen supply. By this heat-conducting compound, a heat transfer of inflowing into the first capacitor fuel cell exhaust air (cathode exhaust air, anode exhaust air or fuel cell mixed exhaust air) on the anode to be provided to make hydrogen possible. Thus, external heaters or heat exchangers for increasing the temperature of the hydrogen, in particular to a temperature above the dew point of the fuel cell exhaust air, and in particular the operating temperature of the fuel cell, waived and even high power requests to the fuel cell system promptly operated. The device according to the invention also avoids uncontrolled condensing out of water and condensation cloud formation on the fuel cell system outlet with all the optical and safety-relevant impairments, such as, for example, B. the formation of ice surfaces at the fuel cell system outlet. The device thus uses energy provided by itself and is thus highly efficient and at the same time energy-saving operable and beyond safe in the application.

The advantages, advantageous effects and developments shown for the method according to the invention are also applicable to the device according to the invention.

According to an advantageous development of the device according to the invention, the first capacitor is fluid-conductively connected to the cathode gas supply and / or the fuel cell. As a result, a moistening of the cathode gas to be supplied to the cathode is achieved on the one hand. External humidifying devices can be dispensed with. Better humidification can also be used for an increase in the efficiency of the fuel cell system, whereby less heat is produced, for example, with the same electrical power supplied. Alternatively, therefore, an increase in the electrical power can be made possible. In addition, the water recovered by the heat transfer from the fuel cell exhaust air to the anode-side hydrogen can also be used for cooling the fuel cell. This ensures reliable operation of the fuel cell system, even without external cooling devices, even at high power requests.

Further advantageous for increasing the performance of the device according to the invention by optimizing the heat transfer, the heat exchanger of the first capacitor comprises a gas / gas heat exchanger or two associated liquid / gas heat exchanger.

A further advantageous development provides that the device comprises a second capacitor, which is in fluid communication with the first capacitor, wherein the first capacitor and the second capacitor are connected in particular in series. As a result, the Wasserabscheidekapazität is significantly increased, which contributes to the increase in performance of the device. Advantageously, the second condenser also comprises a heat exchanger and a water separator. The heat exchangers of the first condenser and the second condenser can advantageously be connected in series and further advantageously be integrated into one component in order to save installation space, with the capacitors also advantageously sharing a water separator for reasons of space efficiency.

Further advantageously, the device comprises one with the first capacitor and / or the second condenser fluidly communicating water tank. As a result, recovered water from the fuel cell exhaust air can be stored and used again as needed. Thus, even high power requests can be spontaneously operated by sufficient humidification of the cathode gas and high cooling capacity in the fuel cell.

Further according to the invention, a motor vehicle is described which comprises a device as disclosed above. The motor vehicle is characterized by a high power density and, due to the elimination of space-consuming devices for anode gas heaters, external cooling devices and humidifiers, by a compact design. Since the formation of condensation clouds is effectively avoided by the device according to the invention, the motor vehicle is also advantageous in safety-relevant aspects, since the formation of ice surfaces in the environment of the motor vehicle and an uncontrolled condensation of water can be avoided.

The advantages, advantageous effects and developments shown for the method and the device according to the invention are also applicable to the motor vehicle according to the invention.

The invention also describes the use of cold of hydrogen present in a hydrogen storage and / or a hydrogen supply for condensing water from the fuel cell exhaust air of a fuel cell. This makes it possible to dispense with external heating devices, which bring the hydrogen to operating temperature.

• – Das Verfahren ist einfach ohne hohen technischen Aufwand umsetzbar.
• – Durch das Verfahren kann effektiv Energie für den Betrieb eines Brennstoffzellensystems eingespart werden.
• – Zusätzliche Befeuchtung von Kathodengas und Kühlung der Brennstoffzellen können ohne externe Vorrichtungen bereitgestellt werden.
• – Das Verfahren trägt zur Erhöhung der Leistungsdichte des Brennstoffzellensystems bei.
• – Die Vorrichtung ist hoch effizient in der Leistungsausbeute, energiesparend und sicher in der Anwendung.
• – Kondensationswolken und sich daraus entwickelnde Problematik mit Eisbildung werden effektiv vermieden.

Due to the solutions according to the invention and their developments, the following advantages result:

• - The process is easy to implement without high technical complexity.
• - By the method can be effectively saved energy for the operation of a fuel cell system.
• Additional humidification of cathode gas and cooling of the fuel cells can be provided without external devices.
• The method contributes to increasing the power density of the fuel cell system.
• - The device is highly efficient in power yield, energy saving and safe in the application.
• - Condensation clouds and the resulting problem with ice formation are effectively avoided.

Further details, features and advantages of the invention will become apparent from the following description and the figures. Show it:

1 a partial view of a device according to a first embodiment of the present invention,

2 a schematic representation for illustrating the method according to the invention,

3 a partial view of a device according to a second embodiment of the present invention,

4 a partial view of a device according to a third embodiment of the present invention,

5 a partial view of an apparatus according to a fourth embodiment of the present invention and

6 a diagram illustrating the temperature profile during the execution of the method according to the invention.

The present invention will be explained in detail with reference to exemplary embodiments. In the figures, only the aspects of the device according to the invention or of the method according to the invention which are of interest here are shown; all other aspects have been omitted for the sake of clarity. Furthermore, like reference numerals represent like elements.

1 shows a section of a schematic representation of a device 15 according to a first embodiment of the present invention.

The device 15 includes a fuel cell 3 with a cathode and an anode, the cathode having a cathode gas supply 4 For example, for supplying oxygen or air to the cathode, is connected. To an output of the fuel cell 3 is a fuel cell exhaust pipe 5 for discharging fuel cell exhaust air arranged.

The anode of the fuel cell 3 is via a hydrogen supply 2 with a hydrogen storage 1 connected. The fuel cell 3 is designed for operation with hydrogen gas, wherein water is formed by reaction with the cathode gas. The hydrogen storage 1 stores hydrogen as fuel for the fuel cell 3 in gaseous or liquid form, at a temperature at least 20 ° C below a temperature of the exhaust air in the Brennstoffzellenabluftleitung 5 lies. Preferably, in the hydrogen storage 1 Hydrogen stored at a temperature of less than about 0 ° C and is stored under pressure.

The fuel cell exhaust pipe 5 includes a first capacitor 7 in which the fuel cell exhaust air via the fuel cell exhaust line 5 is initiated. The first capacitor 7 has at least one heat exchanger and at least one water separator.

To the first capacitor 7 is a water drainage pipe 8th for discharging in the first capacitor 7 separated water from the fuel cell exhaust connected to a water tank 9 opens, which serves to store the separated water. That in the water tank 9 stored water can for example by means of a conveyor 10 , such as As a pump, via a humidification 12 the cathode gas supply 4 are supplied, so that the condensed from the fuel cell exhaust air and separated water for humidification of the fuel cell 3 to be supplied cathode gas, or for cooling the fuel cell 3 , can be used.

As already stated, the first capacitor comprises 7 a heat exchanger and a Wasserabscheidevorrichtung. The first capacitor 7 is with the hydrogen supply 2 thermally conductive connected. The heat contained in the fuel cell exhaust air and the heat of condensation are thus on the hydrogen supply 2 , and thus on the in the hydrogen supply 2 contained hydrogen, transmitted. The in 1 illustrated arrow inside the first capacitor 7 stands for the heat transfer 6 from the fuel cell exhaust air to the anode-side hydrogen. The in the hydrogen supply 2 contained hydrogen is thus heated and preferably brought directly to operating temperature. The fuel cell exhaust air is due to the heat transfer 6 cooled so that water condenses out of it and deposited in the water separator and the water drainage line 8th from the first capacitor 7 discharged and in the water tank 9 is stored. There is a substantially closed water cycle, wherein the cathode gas supply 4 supplied water for the moistening of the cathode gas from the fuel cell exhaust air by condensation in the first capacitor 7 is recovered under the transfer of heat to the anode to be supplied hydrogen.

2 is a schematic representation for illustrating the method according to the invention. In the section shown here are the two possible options for the heat transfer from the first capacitor 7 represented, namely a heat transfer to that in the hydrogen supply 2 contained hydrogen 6a and a heat transfer to the in the hydrogen storage 1 contained hydrogen 6b , Also possible is a combined heat transfer to both in the hydrogen supply 2 contained hydrogen as well as in the hydrogen storage 1 contained hydrogen.

3 is a partial view of a device 25 according to a second embodiment of the present invention. In comparison to the device 15 out 1 Here two capacitors are connected in series. More specifically, two heat exchangers 7b and 7c connected in series with a water separator 7a are connected. The two capacitors thus share a water separator 7a , The heat exchanger 7b corresponds to the heat exchanger of the first capacitor 1 , This is for the heat transfer to the in the hydrogen supply 2 responsible for hydrogen. The second heat exchanger 7c serves for precooling the fuel cell exhaust air, so that in total a larger amount of water condenses out of the fuel cell exhaust air and a larger amount of heat can be transferred to the hydrogen.

4 is a partial view of a device 35 according to a third embodiment of the present invention. Compared to the devices 15 and 25 out 1 and 3 includes the device 35 out 4 a first capacitor 7 and additionally two more heat exchangers 13 . 14 , So is in hydrogen storage 1 a hydrogen storage heat exchanger 13 and in the hydrogen supply 2 a low temperature heat exchanger 14 arranged. From the hydrogen storage 1 becomes the anode of the fuel cell 3 via the hydrogen supply 2 Supplied hydrogen. This is this purpose in the low-temperature heat exchanger 14 heated and brought to operating temperature. After passing through the low-temperature heat exchanger 14 is at least temporarily and / or at least a portion of the heated hydrogen in a hydrogen line 19 derived and the hydrogen storage heat exchanger 13 fed. There transfers the the hydrogen storage heat exchanger 13 supplied hydrogen heat on the in the hydrogen storage 1 contained hydrogen. The hydrogen is thereby preheated. The amount of hydrogen storage heat exchanger 13 via the hydrogen line 19 zuzuleitendem hydrogen is via a three-way valve 16 controlled. Due to the pressure difference in the tank, it is advantageous to perform this part before the expansion of the hydrogen to operating pressure / control pressure.

The hydrogen, the hydrogen storage heat exchanger 13 has gone through, due to the in the hydrogen storage 1 contained Hydrogen transferred heat back to a lower temperature. He is from the hydrogen storage heat exchanger 13 via a hydrogen line 18 discharged. The hydrogen line 18 is via a three-way valve 11 with the first capacitor 7 connected so that the recooled hydrogen from the hydrogen line 18 the first capacitor 7 can be fed to where it passes through the first capacitor 7 contained heat exchanger is heated by transfer of heat from the fuel cell exhaust air. The newer in the first capacitor 7 heated hydrogen is about a hydrogen power 20 discharged and via the three-way valve 16 the anode of the fuel cell 3 fed.

The device 35 includes another hydrogen line 17 that the hydrogen supply 2 over the three-way valve 11 with the first capacitor 7 combines. Because in the hydrogen line 17 contained hydrogen directly from the hydrogen storage 1 comes and not the low-temperature heat exchanger 14 has passed through, he has a very low temperature and can in the first capacitor 7 absorb a high amount of heat, whereby a large amount of water from the fuel cell exhaust air can be condensed out.

In the device 35 out 4 no water tank is provided, so that in the water separator of the first capacitor 7 separated water directly over the drainage pipe 8th is discharged from the device. But it is also possible to provide a water tank and this with the cathode gas supply 4 or directly with the fuel cell 3 connect via an appropriate supply line.

5 is a partial view of a device 45 according to a fourth embodiment of the present invention. contraption 45 includes like device 15 out 1 a first capacitor 7 and additionally a hydrogen storage heat exchanger 13 , Hydrogen gets out of the hydrogen storage 1 via the hydrogen supply 2 in the first capacitor 7 directed. There takes place a heat transfer of heat from the fuel cell exhaust air to the hydrogen, which is heated by it. At the same time the fuel cell exhaust air is cooled and contained water condenses out of it, via the water drainage line 8th from the first capacitor 7 is discharged.

Heated hydrogen is released after passing through the first capacitor 7 via the hydrogen line 20 and a three-way valve 21 the anode of the fuel cell 3 fed. About the three-way valve 21 but also in the first capacitor 7 preheated hydrogen via the hydrogen line 19 the hydrogen storage heat exchanger 13 be fed, so that by the heat transfer in the hydrogen storage heat exchanger 13 Hydrogen in the hydrogen storage 1 is heated. The then in the hydrogen storage heat exchanger 13 Once again cooled hydrogen can then also the hydrogen line 20 be supplied, where he, advantageously with out in the first capacitor 7 heated hydrogen mixed, thereby heated and the anode of the fuel cell 3 can be supplied.

6 is a diagram illustrating the temperature profile during the execution of the method according to the invention. In the diagram, the temperature is plotted on the y-axis.

In detail, the diagram shows the temperature profile of the gases using a device that, as in 3 comprising two capacitors connected in series, namely a second capacitor which is arranged in the fuel cell exhaust line at the output of the fuel cell and a first capacitor connected in series to the second capacitor. The first capacitor and the second capacitor have, in contrast to the device 25 out 3 , in each case a heat exchanger and a water separator.

The area P denotes the area of the refrigeration cycle around the second condenser. The second capacitor is in the initial state at a low temperature level. The temperature level R denotes the temperature of the coolant of the second capacitor in the initial state.

Area K represents the area of the fuel cell exhaust air. The fuel cell exhaust air is warm immediately after leaving the fuel cell and thus at a high temperature level. The temperature level A denotes the fuel cell exhaust air temperature when entering the second condenser. By heat transfer 6c the temperature of the fuel cell exhaust air drops to a temperature level B. The temperature level B indicates the temperature that the fuel cell exhaust air has on exiting the second condenser. The heat transfer 6c The amount of heat to be transferred in this case essentially results from the cooling of the fuel cell exhaust air M in the heat exchanger of the second condenser and the heat of condensation N released in the water separation in the water separator of the second condenser.

By the heat transfer 6c the coolant temperature of the second capacitor is raised from the temperature level R to the temperature level S. Thus, a heat transfer T takes place on the coolant of the second capacitor.

The fuel cell exhaust air after passing through the second capacitor has a temperature level B. The fuel cell exhaust air is then fed to the first capacitor. When passing through the first capacitor, cooling of the fuel cell exhaust air M in the heat exchanger of the first condenser and water separation in the water separator of the first condenser takes place again with the release of condensation heat N. The thus released heat amounts M + N are due to a heat transfer 6b , For example, transferred to the hydrogen contained in the hydrogen storage. Alternatively or additionally, a heat transfer to the hydrogen contained in the hydrogen supply can take place. The lower the temperature of the exhaust air can be lowered, the more water can be condensed out of the exhaust air.

In 6 Let's exemplify a heat transfer to the hydrogen contained in the hydrogen storage. In this case, the region L designates the region of the hydrogen storage, but can equally well quantify the region of the hydrogen contained in the hydrogen supply or a combination of the two regions. The hydrogen in the hydrogen storage in the initial state has a low temperature level X. By the heat transfer 6b the temperature of the hydrogen is raised by heat transfer O to a level Y.

In total, this raises the temperature level in the second condenser, lowers the temperature level in the cathode exhaust air and raises the temperature level of the hydrogen contained in the hydrogen storage (and / or the hydrogen supply line).

The foregoing description of the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents.

LIST OF REFERENCE NUMBERS

1

Hydrogen storage

2

Hydrogen feed

3

fuel cell

4

Cathode gas supply

5

Fuel cell exhaust line

6

Heat transfer

6a

Heat transfer to hydrogen in the hydrogen supply

6b

Heat transfer to hydrogen in the hydrogen storage

6c

Heat transfer

7

first capacitor

7a

common water separator of the first capacitor and a second capacitor

7b

Heat exchanger of the first capacitor

7c

Heat exchanger of a second capacitor

8th

Water drain pipe

9

water tank

10

Water conveying device

11

Three-way valve

12

humidifying pipe

13

Hydrogen storage heat exchanger

14

Low temperature heat exchanger

15

contraption

16

Three-way valve

17

Hydrogen line

18

Hydrogen line

19

Hydrogen line

20

Hydrogen line

21

Three-way valve

25

contraption

35

contraption

45

contraption

Claims (10)

Method for operating a fuel cell system, comprising at least one fuel cell ( 3 ) with a cathode and an anode, the cathode having a cathode gas supply ( 4 ), wherein to an output of the fuel cell ( 3 ) a fuel cell exhaust line ( 5 ) is connected, the at least one first capacitor ( 7 ), the at least one heat exchanger ( 7b ) and at least one water separator comprises, wherein the anode via a hydrogen supply ( 2 ) with a hydrogen storage ( 1 ), characterized by the step of transferring heat from the fuel cell exhaust air to the hydrogen to be supplied to the anode while condensing water out of the fuel cell exhaust air in the first capacitor ( 7 ). A method according to claim 1, characterized in that the transfer of heat from the fuel cell exhaust air to the hydrogen in the hydrogen storage ( 1 ) and / or to the hydrogen in the hydrogen feed ( 2 ) he follows. A method according to claim 1 or 2, characterized in that the transfer of heat from the cathode exhaust air and / or the anode exhaust air, in particular from the cathode exhaust air, takes place. Method according to one of the preceding claims, characterized in that the condensed water of the cathode gas supply ( 4 ) and / or the fuel cell ( 3 ) and / or characterized in that the transfer of heat by passing a gas / gas Heat exchanger or by passing two fluid-conducting associated liquid / gas heat exchangers takes place and / or characterized in that the transfer of heat is carried out according to the countercurrent principle. Method according to one of the preceding claims, characterized in that the hydrogen is expanded before or after the transfer of heat. Method according to claim 5, characterized in that the cold released during the expansion of the hydrogen is used to cool the fuel cell exhaust air and / or to condense water out of the fuel cell exhaust air. Method according to one of the preceding claims, characterized in that the fuel cell system comprises a second capacitor, and the method is characterized by the step of condensing water from the fuel cell exhaust air in the second capacitor. Device for carrying out the method according to one of the preceding claims, comprising at least one fuel cell ( 3 ) with a cathode and an anode, the cathode having a cathode gas supply ( 4 ), wherein to an output of the fuel cell ( 3 ) a fuel cell exhaust line ( 5 ) is connected, the at least one first capacitor ( 7 ), the at least one heat exchanger ( 7b ) and at least one water separator comprises, wherein the anode via a hydrogen supply ( 2 ) with a hydrogen storage ( 1 ), characterized in that the first capacitor ( 7 ) with the hydrogen storage ( 1 ) and / or the hydrogen feed ( 2 ) is thermally conductively connected. Apparatus according to claim 8, characterized in that the first capacitor ( 7 ) fluid-conducting with the cathode gas supply ( 4 ) and / or the fuel cell ( 3 ) and / or that the heat exchanger of the first capacitor ( 7b ) comprises a gas / gas heat exchanger or two related liquid / gas heat exchangers. Device according to claim 8 or 9, characterized by a second capacitor connected to the first capacitor ( 7 ) in fluid communication with the first capacitor ( 7 ) and the second capacitor are in particular connected in series and / or characterized by one with the first capacitor ( 7 ) and / or the second condenser in fluid communication associated water tank ( 9 ).

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