EP2258018A1 - Fuel cell system and method for operating a fuel cell system - Google Patents

Abstract

The invention relates to a fuel cell system comprising at least one fuel cell (2) which has an anode region (4) and a cathode region (3) and is arranged in a housing (6), wherein a rinsing medium for rinsing the housing (6) can be introduced into the housing (6), in a region (7) outside the fuel cell (2). According to the invention, a device (16, 17, 18, 19) is provided for drawing off the medium mixture comprising the rinsing medium and contained in the region (7) outside the fuel cell, said device being connected to said region (7) and to an exhaust pipe (15, 15a) leading away from the cathode region (3). The device is designed such that the drawing off of the medium mixture is fluidically coupled to the exhaust flow flowing in the exhaust pipe (15, 15a). The invention also relates to a method for operating such a fuel cell system.

Description

 Fuel cell device and method of operating a fuel cell device

The invention relates to a fuel cell device having at least one fuel cell, which has an anode space and a cathode space and is arranged in a housing. A flushing medium for flushing the housing can be introduced into the housing outside the fuel cell. Furthermore, the invention relates to a method for operating a fuel cell device, in which a flushing medium for flushing the housing, in which a fuel cell is arranged, is introduced into the housing outside the fuel cell.

Such a fuel cell device and such a method is known from WO 2005/099017 A2. There is supplied as flushing medium ambient air from the outside.

In fuel cell systems, it is customary to accommodate the fuel cell or a fuel cell stack with a plurality of fuel cells in a housing. This housing serves on the one hand, the

On the other hand, it serves to catch any leaks in the fuel cell stack, in particular the anode, and the associated hydrogen emissions and to direct it to a specific location in order to protect fuel cell stacks from external influences such as dirt, dust, water, etc. The problem here is that it is due to the leakage of the fuel cell stack Within the housing can come to gas mixtures, which form a combustible or explosive gas mixture due to their composition. This should be avoided in the prior art in that the housing is constantly flowed through with fresh air, which is conveyed by means of a blower or fan from the environment into the housing. The fan of the fuel cell device according to WO 2005/099017 A2 also serves to supply air to the cathode. In addition to the inflow line, a discharge line is arranged on the housing, which opens, for example, in an exhaust air or exhaust gas channel. The permanent flow through the housing with fresh air to ensure that no unwanted hydrogen-air mixture is formed in the housing. A problem here is that extra a separate blower must be provided in order to realize the flow can. This fan must be driven accordingly with a motor, which has a negative effect on the overall efficiency of the system. However, it does not contribute to energy conversion. The blower usually has a limited capacity and thus can only promote a certain, relatively small air flow, whereby a permanent operation is required.

Furthermore, a sensor can be arranged within the housing, which measures the hydrogen concentration in the housing. If this concentration is above a certain limit, the entire fuel cell system is switched off, as the fan may not be able to deliver more or not sufficiently to reduce the hydrogen concentration in the housing accordingly. A flushing with ambient air is, inter alia, disadvantageous because it contains about 21% oxygen, which ultimately represents a component of the gas mixture, which can be potentially explosive with appropriate hydrogen concentration. Furthermore, in a permanent operation of the fan, the noise of the fan can be distracting. In this context, fuel cell systems are also known in which, for example, branches behind an air filter unit in the intake of the compressor for the cathode compartment of the fuel cell system, a line which opens into the housing. In this line, a fan is also arranged, which promotes the branched air into the housing. The then again derived from the housing medium is introduced before the compressor in the intake path for the cathode compartment. The gas mixture of the housing is thus supplied to the compressor, which sucks the gas mixture and supplies the cathode space of the fuel cell. The possibly very small amount of hydrogen, which is discharged from the housing with, is then diluted again by the intake air of the compressor from the environment. The gas stream is then compressed and fed to the cathode, where then reacts the very small proportion of hydrogen chemically. This is to ensure that no hydrogen emissions come to the outside or into the environment. For the blower in this branching line, what has already been said above applies, whereby here too the blower is permanently operated at a stationary point and the housing is permanently flushed through.

It is an object of the present invention to provide a fuel cell device and a method of operating a fuel cell device in which an efficient purging of the housing outside of the fuel cell can be ensured without disturbing noise degradation, as occurs by a dedicated blower , And in addition, by the rinsing no unwanted fuel-oxidant mixture is generated.

This object is achieved by a fuel cell device having the features of claim 1, and a Method having the features of claim 22 solved.

A fuel cell device according to the invention comprises at least one fuel cell, which has an anode space and a cathode space and is arranged in a housing. A flushing medium for flushing the housing can be introduced into the housing in a space outside the fuel cell. The fuel cell device comprises a device for diverting the medium mixture contained in the space and having the flushing medium, the device being connected to the interior of the housing and to an exhaust pipe leading away from the cathode space. In addition, the device is designed so that when diverting the medium mixture from the space of the housing, the space and thus also the medium mixture is fluidly coupled to the exhaust gas flowing in the exhaust pipe. Thus, a component can be provided by means of which flushing can be carried out more easily and without a quasi-actively operating component, such as a fan, and in addition it can also be achieved that undesired medium mixtures, in particular undesired hydrogen-air mixtures, are produced. Mixtures in which space is created.

The device is thus, so to speak, a passive unit, whereby a higher reliability can be achieved compared to actively operating units. The device is thus designed so that it uses fluidic relationships to allow the discharge or the suction of the medium contained in the medium mixture. An active component, for example a fan, can therefore be completely dispensed with in order to divert this mixed medium from the housing.

The flushing medium is preferably fresh air introduced from the environment. Preferably, the device is designed so that the exhaust gas flow is a propulsion jet through whose streams the medium mixture is automatically sucked out of the room.

In particular, the device is designed as a pump, preferably as a jet pump. This is very simple and conceptually extremely reliable. Such a jet pump enables the particularly effective implementation of the fluidic relationships with regard to the automatic suction of the medium mixture from the room in conjunction with the flowing exhaust gas flow.

The device, in particular the jet pump, preferably has a constriction with a flow cross section which is reduced in comparison to the flow cross section before and after the constriction. The device is thus designed with regard to its bottleneck - that widens the flow cross section before the bottleneck and also after the bottleneck respectively. In terms of flow, this can also ensure a nozzle effect, for example as with a Laval nozzle. By passing the exhaust gas flow through this constriction, the fluidic coupling for sucking off the medium mixture from the room by connecting this bottleneck with the room can be made particularly suitable.

In particular, it is provided in this context that the device has a line which opens into the space, which branches off from this constriction.

In particular, the opening into the space opening of the line is oriented to the side. In this context, the line can quasi side, in particular horizontally, open into the room. It can also be provided that the opening into the space opening of the line is oriented upward and the line extends in particular vertically upwards (with respect to the direction of gravity). Just by the second solution can be made possible that the upwardly settling in the housing fuel, especially hydrogen or hydrogen-containing gas, can be particularly suitably sucked and thus the housing can be flushed particularly effective.

Preferably, the device discharges the medium mixture out of the space, in particular the line of this device, above (with respect to the direction of gravity) of the fuel cell in the room. This embodiment also allows the aspect to be taken into account that the fuel settles upwards in the space and thus the upwardly depositing fuel emerging from the fuel cell, for example due to leakages, can be flushed out particularly well. Preferably, the housing has an opening for supplying the flushing medium, which is formed below (with respect to the direction of gravity) of the fuel cell. Also, by this configuration, the rinsing effect can be favored, as quasi by the inflow from below or at a level below the fuel cell, the fuel can be driven upwards and there accordingly flushed or derived from the housing. It can also be provided that the housing has an opening for supplying the flushing medium, which is formed above (with respect to the direction of gravity) of the fuel cell.

The opening can advantageously be closed by a closure element, wherein the closure element is in particular electronically controllable. By this configuration can be achieved that the opening is not permanently open, but demand-dependent can be opened and closed. In particular, it is provided that the closing or opening position of the closure element is dependent on the concentration of the fuel in the space of the housing outside of the fuel cell.

This concentration of the fuel can preferably be determined by means of a device for detecting this concentration, in particular a suitable sensor system. This sensor is preferably arranged in the housing outside of the fuel cell. In particular, this sensor is located from the height level above (with respect to the direction of gravity) of the fuel cell, preferably adjacent to the upper cover of the housing.

The device is in particular arranged completely in the housing. As a result, a compact design can be achieved.

In particular, upstream of the device for discharging the medium mixture from the housing, a bypass line for bypassing this device is formed, which branches off from the exhaust pipe of the cathode chamber. As a result, a bypass configuration can be achieved, which makes it possible that the exhaust gas flow is diverted according to the situation and demand. The required for the realization of the fluidic principle proportion of exhaust gas flow can thus be metered very precisely. Thus, depending on the operating phase, the entire exhaust gas flow can be conducted via the device and, on the other hand, it can also be made possible that only a partial flow is passed through the device or the entire exhaust gas flow is conducted via the bypass line.

In particular, the portions of the exhaust gas stream flowing through the device for discharging the medium mixture and via the bypass line are adjustable. Preferably, these are Components of the exhaust gas flow depending on a concentration of fuel in the space of the housing adjustable. In this context, it is particularly preferably provided that the fuel cell device has an adjusting element which can change the flow cross sections of the exhaust gas line with the device on the one hand and the flow cross sections of the bypass line on the other hand. Preferably, this adjustment is electronically controlled and the position can be changed accordingly. This can also be done in particular as a function of the concentration of the fuel in the space in which the medium mixture is located. In particular, the adjusting element is arranged at the branch between the exhaust pipe and the bypass line.

Preferably, the fuel cell device has a catalyst, through which the medium mixture derived from the space can be conducted. By means of this catalyst, the depletion of the fuel contained in the medium mixture can then be made possible in a preferred manner and thus the discharge of a medium mixture with an undesirably high proportion of fuel can be prevented. Preferably, the catalyst is disposed in the conduit extending between the space and the throat of the device for discharging the mixed medium. Of course, the catalyst can also be arranged at a different location on the way between the housing and the environment, whereby the medium mixture is passed over this way.

In a method according to the invention for operating a fuel cell device having at least one fuel cell, which has an anode space and a cathode space and is arranged in a housing, a flushing medium for flushing a space of the housing is introduced into the housing outside the fuel cell. A flowing in an exhaust pipe of the cathode space exhaust stream is fluidly through a device so with the Coupled space that the medium contained in the space and having the flushing medium aspirated from the room, in particular is automatically sucked. By this procedure, it is no longer necessary to provide an active element, such as a fan, in order to achieve this flushing and the discharge of the medium mixture can. Due to fluidic principles, the procedure according to the invention makes it possible to implement a passive procedure, as a result of which component components can be saved and the efficiency of the fuel cell device is not impaired by such active components.

Preferably, the device for discharging the mixed medium from the space is released depending on a concentration of fuel in the space for aspirating the medium mixture. This can be made possible that this device is not permanently active, but is used and used only in specific required operating phases accordingly.

In particular, the space of the housing is flushed with the medium mixture with fresh air.

Advantageous embodiments of the fuel cell device according to the invention and in particular the mode of operation and the relationships of the subject features are also to be regarded as advantageous embodiments of the method according to the invention.

According to the invention, therefore, by the device for deriving the medium mixture, in particular a jet pump, no "active" but a "passive" component or concept is used, which causes increased reliability. The use of the advantageous jet pump requires only a minimum of additional weight and space compared to a system without ventilation of the housing and a considerable less effort in terms of space and weight compared to a system with auxiliary fan and drive motor. By not having to permanently drive a fan, such a jet pump system is more efficient in terms of energy and thus has an increased efficiency over systems known in the art. The resulting by the jet pump larger pressure drop, which occurs due to the required higher pumping power, can be countered that the exhaust air flow or exhaust gas bypasses the jet pump through the bypass line and so the way of a very low pressure drop in the exhaust air path is selected. The adjusting element, in particular a flap, is in this case then set if necessary so that the exhaust gas flow is passed through the jet pump and the medium mixture, in particular the gas mixture, sucks from the housing. Since this preferably always takes place when a certain concentration of the fuel, in particular of the hydrogen, - is determined in the space of the housing with the medium mixture and the rest of the time the exhaust air flow is passed through the bypass line or bypass line, resulting in a lower pressure drop and allows a lower pumping of the compressor, this possibility is highly efficient, since the short-term energy expenditure is very low. Furthermore, due to the flap, which is preferably arranged in the exhaust gas flow, it is also possible to raise the pressure level in the fuel cell stack at least partially, which may be more inefficient overall, but offers the possibility of increasing the pressure in the cathode compartment to the power or the power density of the fuel cell to increase. This is especially true when using the

Fuel cell facility at high altitudes with lower pressures of the case. This also means that even when using the jet pump without the bypass line efficiency losses are relatively low, since the increased cost of pumping power at a higher pressure drop, so when the exhaust stream is passed through the jet pump through the increased pressure in the cathode compartment and thus the higher efficiency of the fuel cell stack can be at least partially compensated.

It can also be provided that the

Fuel cell device is designed so that the exhaust gas flow generated in the cathode compartment and the exhaust gas flow generated in the anode compartment are passed through the jet pump and advantageously used catalyst element need not necessarily be arranged in the connecting the space with the medium mixture with the device for discharging the medium mixture suction line, but also somewhere else in the region of the exhaust air line in which the exhaust air of the cathode, the purged fuel of the anode and the intercepted leaks are passed together via such a catalyst element.

It can also be provided to a safety philosophy to the effect that the adjustment in the exhaust pipe of the cathode chamber is normally set so that the exhaust stream of the cathode chamber in this state always flows through the device for discharging the medium mixture from the room and thus sucks the medium mixture from the housing , This would ensure that, in the case of a defect in the actuator for adjusting the adjusting element, in particular the flap, suction of the mixed media from the housing is nevertheless guaranteed.

Embodiments of the invention are explained in more detail below with reference to schematic drawings. Show it:

1 shows a first embodiment of a BrennstoffZelleneinrichtung invention;

FIG. 2 shows a second embodiment of a fuel cell device according to the invention; FIG.

3 shows a third embodiment of a fuel cell device according to the invention; 4 shows a fourth exemplary embodiment of a fuel cell device according to the invention; 5 shows a fifth embodiment of a fuel cell device according to the invention; 6 shows a sixth embodiment of a fuel cell device according to the invention; and FIG. 7 shows a seventh exemplary embodiment of a fuel cell device according to the invention.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

In Fig. 1, a fuel cell device 1 is shown, which is designed as a mobile fuel cell system and arranged in a vehicle. The

Fuel cell device 1 comprises a fuel cell 2, which has a cathode space 3 and an anode space 4. The cathode compartment 3 and the anode compartment 4 are separated from each other by a PEM (proton exchange membrane) 5. The fuel cell 2 is formed in the embodiment as a PEM fuel cell. The fuel cell device 1 comprises a fuel cell stack with preferably a plurality of fuel cells 2. In the exemplary embodiment, for the sake of clarity, only one fuel cell 2 is shown.

This fuel cell 2 is arranged in a housing 6, which protects the fuel cell 2 from dirt, external influences and damage.

In an inner space 7 of the housing 6 outside of the fuel cell 2, fuel may accumulate during operation of the fuel cell 2 due to leaks of the fuel cell 2 or other processes, which is to be flushed out of the space 7. The anode chamber 4 is supplied via an anode branch fuel, in particular hydrogen or a hydrogen-containing gas. This is in one Storage reservoir or container 8 is stored and is supplied via a feed line 9 to the anode compartment 4. The anode exhaust gas can be completely or partially fed back to the anode via a return line and a recirculation device, for example a pump (not shown). An anode exhaust gas generated during operation of the fuel cell 2 in the anode compartment 4 is discharged via an exhaust pipe 10 from the anode compartment 4 and in particular also discharged into the environment.

In addition, the fuel cell device 1 also comprises a cathode branch with a supply line 11 via which oxidizing agents, in particular oxygen or oxygen-containing gas, such as e.g. Ambient air is conveyed to the cathode compartment 3. In the cathode branch and connected to the supply line 11 and disposed therein is an air filter 12. Downstream of the air filter 12, a compressor 13 is arranged, which is driven by a motor 14 and which promotes the oxidant via the supply line 11 to the cathode space 3.

In addition, the BrennstoffZelleneinrichtung 1 and in particular the cathode branch comprises an exhaust pipe 15, via which the cathode exhaust gas generated in the cathode compartment 3 during operation of the fuel cell 2 is derived. This too is derived in the environment. Of course, a recirculation device can be provided both on the cathode branch and on the anode branch, by means of which the exhaust gas of the cathode chamber 3 is fed back into the supply line 11 or the anode exhaust gas into the supply line 9.

The fuel cell device further comprises a device for discharging the medium formed in the space 7, which comprises the collected fuel and the flushing medium, out of the space 7. The device is designed in the embodiment as a jet pump 16. The jet pump 16 is provided with a sub-element in the exhaust pipe 15 arranged or connected thereto. The jet pump 16 is designed as a passive component. Due to fluidic relationships can be achieved by a suitable design of the jet pump 16 that the medium contained in space 7 can be extracted automatically depending on demand and situation specific. The jet pump 16 is on the one hand connected to the space 7 via a line 17 and on the other hand to the exhaust pipe 15. The effluent from the cathode chamber 3 exhaust gas or the effluent exhaust gas stream flows through the exhaust pipe 15 and thus also through the jet pump 16. By this flowing exhaust gas flow and the connection of the jet pump 16 with the space 7 can due to fluidic relationships, the suction of the medium mixture from space 7 are possible. This is particularly advantageous in that the device or jet pump 16 comprises an element 18 which has a constriction 19. The element 18 is designed so that it is formed in an axial direction and thus in its longitudinal direction and in this context also in the longitudinal direction of the exhaust pipe 15 with a varying flow cross-section. In this context, it is provided that the constriction 19 has a flow cross section which is smaller than the flow cross section before and after this constriction 19. The element 18 of the jet pump 16 is thus formed before and after the constriction 19 with a respective expanded flow cross section, whereby a Principle according to a Laval nozzle can be realized.

At this bottleneck 19, the line 17 opens, see. Entry 20. As shown in the illustration in Fig. 1, the conduit 17 branches off from a location of the housing 6 which, with regard to the observation of the height level (y-direction) above (with respect to the direction of gravity) of Fuel cell 2 is located. This is advantageous because the fuel flowing out of the fuel cell 2 rises upwards in the space 7 (positive y-axis). Direction) settles. In the embodiment shown, the line 17 is oriented so that it emerges quasi horizontally from the housing 6 whereby the opening 21 is quasi-side oriented and thus a lateral suction from the space 7 takes place. The jet pump 16 is thus arranged downstream of the fuel cell 2 and connected to the space 7 and to the exhaust pipe 15.

For flushing the space 7 fresh air 22 is introduced via an opening 23 in the housing 6 from the outside or from the environment. According to the embodiment in FIG. 1, the opening 23 is formed on an underside or on a bottom of the housing 6 and thus realized with respect to the height level below (with respect to the direction of gravity) of the fuel cell 2.

The effluent from the cathode chamber 3 exhaust gas stream, which flows in the exhaust pipe 15, acts in the jet pump 16 as a propulsion jet, which due to the fluidic coupling, the suction of the medium mixture, which has the fresh air 22 and the accumulated in the space 7 fuel, automatically and passively ,

As shown in FIG. 1, it can be seen that the jet pump 16 is arranged outside the housing 6. Moreover, in the embodiment of the fuel cell device 1 shown in FIG. 1, a permanent flushing of the housing 6 is realized. In addition, the medium mixture formed in space 7 is permanently sucked by the jet pump 16 and permanently.

In the embodiment according to FIG. 2, in contrast to the illustration according to FIG. 1, a catalyst 24 is provided, through which the medium mixture extracted from the space 7 is passed. In the shown Fig. 2, the catalyst 24 in the conduit 17 which connects the space 7 and the housing 6 with the element 18 of the jet pump 16, respectively. In the catalyst 24, the hydrogen contained in the fuel-oxidizer mixture or hydrogen-air mixture reacts, so that no or only a very small proportion of hydrogen can get into the environment.

Of course, this catalyst 24 may also be arranged at another point of the flow path of the medium mixture.

In Fig. 3, a further embodiment is shown, which is realized in contrast to the illustration of FIG. 1 to the effect that the jet pump 16 is arranged in the housing 6. In addition, the conduit 17 extends vertically upward (with respect to the direction of gravity) so that the opening 21 is oriented upwardly. This opening 21 is thus located in the upper region of the housing 6, ie where potentially hydrogen accumulates. As a result, the hydrogen accumulated there can be sucked off particularly effectively.

4, a further embodiment is shown in which, in contrast to the embodiment of FIG. 2, an additional bypass line 25 is provided. The bypass line 25 branches off at the branch 26 upstream of the jet pump 16 from the exhaust gas line 15. By this bypass line 25, the jet pump 16 can be bypassed. By means of the bypass line 25, the exhaust gas stream flowing in the exhaust gas line 15 can thus be at least partially directed as needed. For this purpose, it is provided that an adjusting element, which is designed as a flap 27 in the embodiment, is electronically controlled adjustable. The flap 27 is arranged in the embodiment directly to the branch 26 and can be adjusted by a servomotor 28. The adjustment can be done continuously. It is preferably provided that the portions of the exhaust gas flow are derived in accordance with a concentration of the fuel in the space 7 accordingly.

In addition, the configuration with the bypass line 25 has the advantage that during the predominant operating time of the fuel cell device 1, the effluent from the cathode compartment 3 exhaust gas flow along the path of the lower flow resistance can be performed, which is realized by the discharge via the bypass line 25. This is the more effective process in terms of compressor performance. By means of, for example, intermittent actuation of the flap 27, the exhaust gas stream from the cathode side or the cathode chamber 3 can be repeatedly led over the primary exhaust gas line 15a and thus also via the jet pump 16, so that the medium mixture is sucked out of the chamber 7 or drawn in can be. In the embodiment according to FIG. 4, the jet pump 16 and also the bypass 25 and the branch 26 are arranged outside the housing 6.

In Fig. 5, a further embodiment is shown, in which, in contrast to the illustration of FIG. 4, the branch 26 and the jet pump 16 and a part of the bypass line 25 are disposed within the housing 6. In addition, a control unit 29 is shown in Fig. 5, which is electronically connected to the servo motor 28 and with a device for detecting the concentration of the fuel in the space 7, in particular the sensor 30, signal or data leading. Depending on the detected by means of the sensor 30 concentration of the fuel, the flap 27 can be adjusted depending on demand by the activatable by the control and / or regulating unit 29 servomotor 28.

Upon detection of a specific, fixed limit value of the fuel concentration, a signal is sent to the control unit. and / or control unit 29. This unit 29 processes the signal and then actuates the flap 27 by means of which the path of the exhaust gas stream from the cathode chamber 3 via the jet pump 16 and thus via the exhaust pipe 15a predetermined and thereby the medium mixture from the space 7 of the housing. 6 can be sucked off. The actuation of the flap 27 and thus the path of the exhaust gas flow of the cathode chamber 3 is thus regulated as a function of the hydrogen concentration in the space 7. Furthermore, the control of the flap 27 can also be controlled or regulated by other or further parameters. In this context, as a parameter, for example, the air mass flow and the compressor speed of the compressor 13 may be mentioned. The inflow of fresh air 22 takes place here via the attached opening 23 in the bottom of the housing.

In Fig. 6, another embodiment is shown in which no opening 23 is formed in the bottom of the housing 6, but an opening 31 at a lateral location of the housing 6, which in terms of height level above (with respect to the direction of gravity ) of the fuel cell 2 is arranged. In this embodiment, the opening 31 can be closed by means of a closure element 32, wherein the closure element 32 can be controlled by means of the control and / or regulating unit 29. For example, the closure element 32 can be actuated magnetically. Here too, a signal or data-conducting connection is realized by means of a signal line, as in the signal or data-conducting connection to the sensor 30 and the servomotor 28. If a concentration of the fuel in the space 7 is detected, which exceeds a certain limit occurs a signal from the sensor 30 to the unit 29. This processes the signal accordingly and there is a signal to the flap 27 and a signal to the closure element 32, which releases the opening 31. After dropping the concentration of the fuel in space 7 of the housing 6 or after a specified time This again means that the housing 6 is closed again, on the one hand the opening 31 is closed by the closure member 32 and on the other hand, the jet pump 16 is bypassed by the Flap 27 is adjusted so that the exhaust gas flow emerging from the cathode chamber 3 is passed completely through the bypass line 25. This closed position of the closure element 32 and the position of the flap element 27 closing the exhaust gas line 15a are shown in FIG.

In Fig. 7, an embodiment of the fuel cell device 1 is shown, in which, in contrast to the embodiment in Fig. 6, the closure element 32 is shown in the open state. In addition, the flap 27 is shown in a state in which the bypass line 25 is completely closed and the exhaust gas flow emerging from the cathode chamber 3 is conducted completely via the exhaust gas line 15a and thus also via the jet pump 16.

Individual features or feature combinations of a specific embodiment are of course connectable with features and feature combinations of other examples to generate further embodiments. In addition, features or feature combinations not mentioned in the exemplary embodiments are, of course, to be understood as supplements to the respective exemplary embodiments. LIST OF REFERENCE NUMBERS

1 fuel cell device

2 fuel cell

3 cathode compartment

4 anode compartment

5 PEM

6 housing

7 room

8 storage 9,11 supply lines 10,15 exhaust pipes

12 air filters

13 compressor

14 engine

16 jet pump

17 line

18 element

19 bottleneck

20 junction

21 opening

22 fresh air 23.31 openings

24 catalyst

25 Bypass 26 Junction

27 flap

28 servomotor

29 control unit

30 sensor

32 closure element

Claims

20Patentansprüche

A fuel cell device having at least one fuel cell (2) which has an anode space (4) and a cathode space (3) and is arranged in a housing (6), in which a flushing medium for flushing the housing (6) into the housing (6 ) can be introduced into a space (7) outside the fuel cell (2), characterized by a device (16, 17, 18, 19) for diverting the medium mixture contained in the space (7) and having the flushing medium, which communicates with the space (7 ) and one of the cathode chamber (3) discharging exhaust pipe (15, 15a) is connected and which is designed so that the discharge of the medium mixture with the in the exhaust pipe (15, 15a) flowing exhaust gas flow is coupled fluidly.

2. Fuel cell device according to claim 1, characterized in that the flushing medium is fresh air introduced from the environment.

3. fuel cell device according to claim 1 or 2, characterized in that the device (16, 17, 18, 19) is formed so that the exhaust gas stream is a propulsion jet, by its currents 21

the medium mixture is automatically sucked out of the space (7).

4. Fuel cell device according to one of the preceding claims, characterized in that the device (16, 17, 18, 19) comprises a jet pump (16).

5. fuel cell device according to one of the preceding claims, characterized in that the device (16, 17, 18, 19) has a constriction (19) with a reduced compared to the flow cross-section before and after the constriction (19) flow cross-section.

6. Fuel cell device according to claim 5, characterized in that the device (16, 17, 18, 19) has a in the space (7) opening out line (17) which branches off from the constriction (19).

7. fuel cell device according to claim 6, characterized in that in the space (7) opening out opening (21) of the conduit (17) is oriented with respect to the direction of gravity to the side.

8. fuel cell device according to one of claims 1 to 6, characterized in that 22

the opening (21) of the duct (17) opening into the space (7) is oriented upwards with respect to the direction of gravity.

9. Fuel cell device according to one of the preceding claims, characterized in that the device (16, 17, 18, 19), in particular the conduit (17), with respect to the direction of gravity above the fuel cell (2) with the housing (6 ) is connected and in the room (7) opens.

10. Fuel cell device according to one of the preceding claims, characterized in that the housing (6) has an opening (23) for supplying the flushing medium (22) which is formed with respect to the direction of gravity below the fuel cell (2).

11. Fuel cell device according to one of the preceding claims 1 to 9, characterized in that the housing (6) has an opening (31) for supplying the flushing medium (22), which with respect to the direction of gravity above the fuel cell (2) is.

12. Fuel cell device according to claim 10 or 11, characterized in that the opening (23, 31) by a closure element (32) is closable, which is electronically controllable. 23

13. Fuel cell device according to one of the preceding claims, characterized in that the device (16, 17, 18, 19) completely in the

Housing (6) is arranged.

14. Fuel cell device according to one of the preceding claims, characterized in that upstream of the device (16, 17, 18, 19), a bypass line (25) for bypassing the device (16, 17, 18, 19) of the exhaust pipe (15, 15 a ) branches off.

15. Fuel cell device according to claim 14, characterized in that via the device (16, 17, 18, 19) and via the bypass line (25) flowing portions of the exhaust gas flow are adjustable.

16. Fuel cell device according to claim 15, characterized in that the proportions are adjustable as a function of a concentration of the fuel in the space (7).

17. Fuel cell device according to claim 15 or 16, characterized in that the proportions by means of an adjustable, preferably electronically controllable, adjusting element (27) are adjustable.

18. Fuel cell device according to one of the preceding claims, characterized by 24

a catalyst (24) through which the medium mixture derived from the space (7) is passable.

19. Fuel cell device according to claim 18, characterized in that the catalyst (24) is arranged in the between the space (7) and the constriction (19) of the device (16, 17, 18, 19) extending line (17).

20. Fuel cell device according to one of the preceding claims, characterized by a device (22) for detecting the concentration of fuel in the space (7) of the housing (6) outside the fuel cell (2).

21. Fuel cell device according to claim 20, characterized in that the device (22) is arranged inside the housing (6) and outside the fuel cell (2).

22. A method of operating a fuel cell device

(1) with at least one fuel cell (2), which has an anode space (4) and a cathode space (3) and in a housing (6), wherein a flushing medium (22) for flushing a space (7) of the housing (6) is introduced into the housing (6) outside the fuel cell (2), characterized in that an exhaust gas flow flowing in an exhaust pipe (15, 15a) of the cathode space (3) is fluidically conveyed through a device (16, 17, 18, 19 ) is coupled to the space (7), that in the space (7) contained and the 25

Rinsing medium (22) having medium mixture is sucked out of the space (7).

23. The method according to claim 22, characterized in that the device (16, 17, 18, 19) is released depending on a concentration of the fuel in the space (7) for sucking off the medium mixture.

24. The method according to claim 22 or 23, characterized in that the space (7) is purged with fresh air.

25. The method according to any one of claims 22 to 24, characterized in that the effluent from the cathode compartment (3) exhaust stream depending on demand, preferably depending on the Konzentratic of fuel in the space (7), via the exhaust pipe (15, 15a) and / or a by-pass line (25) branching off from the exhaust pipe (15, 15a) upstream of the device (16, 17, 18, 19).