WO2010040513A1 - Fuel cell unit having at least one fuel cell and method for operating a fuel cell unit - Google Patents

Abstract

The invention relates to a fuel cell unit having at least one fuel cell (2) and having a device (3) for feeding a reaction medium to and discharging discharge medium from the fuel cell (2), and having a humidifier (6) that is connected to the device (3) and to the fuel cell (2), wherein the device (3) comprises a bypass line (7, 13) that branches off from a main line (4, 12) of the device (3) in front of the humidifier (6) in the flow direction of one of the media, and wherein a passively operating valve (10) is disposed in the bypass line (7, 13) and/or a passively operating valve (10) is disposed in the main line (4, 12). The invention further relates to a method for operating a fuel cell unit.

Description

 Fuel cell device with at least one fuel cell and method for operating a fuel cell device

The invention relates to a fuel cell device with at least one fuel cell and a device for supplying a reaction medium for and for discharging purge medium from the fuel cell, and a humidifier, which is connected to the device and the fuel cell. Furthermore, the invention relates to a method for operating a fuel cell device with at least one fuel cell.

From US Pat. No. 6,884,534 B2, a fuel cell system is known in which a reaction medium is supplied to a fuel cell stack, to which end a compressor is provided which is arranged upstream of the fuel cell. In addition, a humidifier is disposed upstream of the fuel cell, and a bypass line is also passed around the humidifier, in which an actively electronically controlled valve is arranged.

Moreover, DE 101 10419 A1 discloses a fuel cell system which likewise comprises a fuel cell and a humidifier. From a leading away from the fuel cell discharge line, which passes through the humidifier branches off downstream of the humidifier from a bypass, in which a check valve is arranged. This trained as a return device bypass device can either open between the humidifier and the fuel cell in a supply line for supplying reaction medium to the fuel cell or can be recycled between the humidifier and the fuel cell in the discharge line. In all embodiments, it is therefore provided that the discharged from the fuel cell medium initially passes in an unchanged manner through the humidifier and only then diverted. A specific humidification or an embodiment, to what extent and with which Moist medium flows through the humidifier, can not be done or only very inadequate.

In addition, actively controlled valves, as they are known from the first-mentioned prior art, very expensive and error-prone and it consuming control loops are needed. Therefore, the probability of default is very high and the functionality is limited.

It is an object of the present invention to provide a fuel cell device and a method for operating a fuel cell device, in which or in which the mode of operation for controlling the humidification of the fuel cell is made more robust and with less effort. In addition, the operating state-dependent humidification of supplied medium to the fuel cell is to be made more precise and needs-based.

These objects are achieved by a fuel cell device having the features of claim 1 and a method comprising the features of claim 15.

A fuel cell device according to the invention comprises at least one fuel cell and a device for supplying a reaction medium to the fuel cell and for discharging purge medium from the fuel cell. Furthermore, the fuel cell device comprises a humidifier, which is connected to the device and the fuel cell. By means of this humidifier, the reaction medium and / or the discharge medium is moistened. The device further comprises a bypass line which branches off in the flow direction of one of the media in front of the humidifier from a main line of the device, wherein a passively operating valve in the bypass line and / or a passively operating valve in the main line is arranged. By means of such a design of a fuel cell device, an adjustment of the degree of moisture of one of the media, in particular of the reaction medium supplied to the fuel cell, can be achieved as needed. Moreover, it is no longer necessary to use expensive to control active valves, whereby the robustness of the fuel cell system with regard to the correct adjustment of the degree of moisture can be improved. In this regard, therefore, the susceptibility to errors in the humidity setting and the probability of failure can be reduced. In this regard, moreover, the device has a bypass line or a bypass, which branches off in the flow direction of one of the media in front of the humidifier from a main line. In this regard, therefore, this bypass line is designed so that the medium is not recycled as in the prior art, as is done there by branching a bypass line to the humidifier from the main line, but it should be created virtually a way with which the humidifier can be bypassed, so that even in an extreme case, no medium at all through the humidifier on this associated main line to which the bypass is connected, is passed. In principle, therefore, this embodiment of a bypass line and the purpose of use functionally have a very different orientation than is provided in the prior art.

The bypass line is arranged and configured such that medium to or from the fuel cell in front of the humidifier is at least partially branched off and is conducted past the humidifier, without it being routed through the humidifier (or subsequently). Only in this way can a moisture adjustment, in particular a moisture reduction, be achieved. In the prior art, this is not possible since it is always first passed through the humidifier, that is always moistened, and then carried out a return.

In particular, it is provided that the fuel cell device has a fuel cell stack with a plurality of fuel cells. Preferably, a fuel cell is designed as a PEM (proton exchange membrane) fuel cell. In particular, the fuel cell device is designed as a mobile fuel cell system, and can be arranged in particular in a vehicle, preferably a motor vehicle.

Especially for the operation of PEM fuel cells, it is necessary to moisten the fuel cell supplied air or the oxidant through a humidifier. However, the required moisture content of the air supplied to the fuel cell for optimal operation of the fuel cell stack may not always be constant, but it must be variable depending on the operating condition. This can be carried out, for example, as a function of the magnitude of the current load, for example a partial load or a full load, or depending on specific further operating phases, such as, for example, a start-up or a shut-down of the fuel cell device.

Especially by this specific embodiment and arrangement of the bypass line and in particular by the use of at least one passively operating valve This requirement can be met in a particularly reliable and yet effortless manner.

A passively operating valve is understood to be one which is not electronically controlled, but which is controlled by the fluid flow or the medium flow itself. An opening and closing of this valve thus takes place as a function of the fluid flow, in particular the pressure of the fluid flow.

In particular, the passive valve is a passive check valve. This is a particularly robust embodiment, which can also be realized relatively inexpensively beyond.

In addition, such an embodiment allows the use in a wide variety of environmental conditions, which works just in the use of a fuel cell system in a vehicle in a variety of locations and under different environmental conditions, such as temperature and weather, reliable.

Preferably, the passively operating system is designed so that it automatically opens at a pressure drop threshold between 10 mbar and 200 mbar, preferably between 100 mbar and 200 mbar, in particular at 150 mbar. Especially with such pressures, when using a fuel cell device in a vehicle, it is particularly advantageous to be able to precisely enable the operating phase-specific adjustment of a moisture content in combination with the bypass line and the arrangement of the passively operating valve in the bypass line and / or the main line.

The passively operating valve is preferably arranged in the bypass line, and an actively operating valve, in particular an electronically controlled shut-off valve, is arranged in the main line. In such an embodiment, at least one valve is thus arranged on the one hand in the bypass line, on the other hand in the main line, these valves being designed differently with regard to their functional design and their mode of operation.

It is preferably provided that the actively operating valve is arranged in the main line after the diversion of the bypass line from the main line and in front of the humidifier. By means of this embodiment, it can be achieved in specific operating phases that the path through the humidifier via the main line is completely shut off and thus basically no medium can pass through the humidifier at all. This is particularly advantageous when a completely dry air or a completely dry medium for the fuel cell is required. Thereby, a condensation of water in the medium can be prevented, whereby even at low ambient temperatures, a freezing of such water in the fuel cell can be prevented. Especially in the start-up scenario or the shut-down scenario of the fuel cell device, this is particularly advantageous because then only extremely dry medium, especially extremely dry air, is passed through the fuel cell.

The check valve may comprise a membrane and / or a spring.

In particular, it is provided that the fuel cell device further comprises a conveyor, by means of which the reaction medium and / or the discharge medium can be placed in a flow state. Preferably, this conveyor is designed as a fan or compressor, which is arranged upstream of the fuel cell.

With increasing medium flow, in particular increasing gas flow, from this conveyor, the pressure loss via the humidifier increases. From a certain pressure drop threshold, which can be, for example, 150 mbar, the passive valve opens automatically, so that gas is passed around the humidifier through the bypass or the bypass line. In addition, a normal shut-off valve in the form of an actively operating valve in the main line from the conveyor to the humidifier can be arranged downstream of the branch of the bypass line from the main line. In particular, in a normal operation of the fuel cell device, this actively operating valve is opened, so that the reaction medium, in particular the oxidizing agent, passes through the humidifier and is thus moistened. Especially in the specific operating phases of the start-up and the shut-down mentioned above, the humidity of the medium conducted through the fuel cell must be lower than in said normal operation in order to be able to prevent condensation or freezing of water in the fuel cell. Preferably, especially in these cases, the actively operating valve is then completely closed. The medium flow now flows completely through the bypass line with the passive valve, which opens automatically after a brief increase in pressure. As a result, very dry air flows into the Fuel cell and a condensation or freezing of water in the fuel cell is prevented.

In a further embodiment, it can also be provided that the passively operating valve is arranged in the main line and the bypass line is valve-free. This means that at least no passively operating valve is arranged in the bypass line, in particular basically no valve is arranged.

Preferably, the actively operating valve is located in the main line after the branch of the bypass line from the main line and in front of the humidifier.

In this embodiment too, the valve, which is preferably designed as a passive check valve, may comprise a membrane and / or a spring. Again, it is provided that from a certain pressure drop threshold (for example, from 10 mbar, preferably from 150 mbar) opens this check valve automatically, so that gas is passed through the humidifier. The amounts of gas that flow through the humidifier and through the bypass or the bypass line depend on the respective pressure losses of the humidifier and the bypass line. Below said pressure drop threshold, i. at lower flow rates, the medium supplied to the fuel cell is passed completely around the humidifier through the bypass line. This is the case in particular in the case of the named start-up scenario or in the shut-down scenario in which the fuel cell is operated with lower power and thus lower air volume.

It is preferably provided that additionally in the bypass line a pressure loss adjusting device, for example in the form of a throttle valve or a diaphragm or another valve, is arranged. As a result, the respective amounts of airflow through the bypass line and through the humidifier can be better adapted to the given pressure losses of the humidifier.

Preferably, in these mentioned embodiments, the main line is a feed line leading to the cathode of the fuel cell.

In particular, it is provided that the bypass line rejoins the humidifier in the main line again. It can also be provided that the main line is a discharge line for discharging exhaust gas from the fuel cell. In particular, it is provided that the device for supplying a reaction medium for and for discharging discharge medium from the fuel cell has both a supply line and a discharge line.

Even if the main line is a discharge line for discharging exhaust gas from the fuel cell, the corresponding arrangement of the passive-operating valve in the bypass line and / or the arrangement of an actively operating valve in the main line can be provided. Likewise, here also an embodiment may be provided, in which the bypass line is valve-free and the passively operating valve is arranged in the main line between the humidifier and the diversion of the bypass line from the main line.

As an alternative to the embodiments in which the main line represents the supply air line, a bypass line can thus also be arranged around the exhaust side of the humidifier.

Particularly advantageous in the embodiments in which the main line is the supply line for supplying a reaction medium to the fuel cell, and the bypass line branches off from this supply line, an advantageous valve arrangement provided in this regard, since then the valves are advantageously arranged in the dry supply air flow of the fuel cell, so that This can also at least significantly reduce corrosion of the valves or freezing of the valves.

In a method according to the invention for operating a fuel cell device having at least one fuel cell and a device with which a reaction medium is supplied to the fuel cell and a discharge medium discharged from the fuel cell and the reaction medium and / or the discharge medium is passed through a humidifier, which is connected to a main line of the device the device has a bypass line, which is branched off in the direction of flow of a medium in front of the humidifier of a main line of the device, and a passively operating valve in the bypass line and / or a passive valve in the main line is arranged, this becomes passive operating valve is open depending on exceeding a pressure drop threshold on the humidifier and / or on the valve itself. By doing so, a much more needs-based and more precise adjustment of the moisture content of the media conducted through the fuel cell can be achieved, this being achieved by much more robust, less expensive components, in particular by the passive valve, can be guaranteed.

Advantageous embodiments of the fuel cell device according to the invention are to be regarded as advantageous embodiments of the method according to the invention.

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

Showing:

Fig. 1 is a schematic representation of a first embodiment of a fuel cell device according to the invention;

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

3 shows a third embodiment of a fuel cell device according to the invention; and

4 shows a fourth 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 the following figures, only the components of a fuel cell device which are sufficient for explaining the invention are shown. Of course, a fuel cell device also includes additional components, which are not here in the foreground and therefore also not shown or explained below.

In Fig. 1, a first embodiment of a fuel cell device 1 is shown, which is designed as a mobile fuel cell device and can be arranged in a vehicle. The fuel cell device 1 comprises at least one fuel cell 2, which is designed as a PEM fuel cell. Preferably provided that the fuel cell device 1 has a fuel cell stack with a plurality of such fuel cells 2.

The fuel cell device 1 further comprises a device 3 for supplying a reaction medium, in particular an oxidizing agent, to the fuel cell 2, in particular to the cathode space. The oxidizing agent is preferably oxygen or an oxygen-containing gas.

The device 3 comprises a line system with a main line 4, which is connected to a compressor 5. In addition, the main line 4 is connected to the fuel cell 2, in particular the cathode space of the fuel cell 2. Furthermore, the main line 4 is connected to a humidifier 6, which is for wetting the fuel cell 2 supplied media, in the embodiment of FIG. 1, in particular of the oxidizing agent is formed. In this regard, in the embodiment according to FIG. 1, the main line 4 is connected to the supply air region of the humidifier 6 for supplying the oxidizing agent to the fuel cell 2.

The device 3 further comprises a bypass line 7, which branches off at a branch 8 from the main line 4 and opens at a junction 9 in the main line 4. The branch 8 is formed between the compressor 5 and the humidifier 6, the junction 9 being formed between the humidifier 6 and the fuel cell 2. In addition, the fuel cell device 1 comprises a passively operating valve, which is realized in the embodiment shown as a passive-acting check valve 10. This passively operating check valve 10 is arranged in the bypass line 7. The passive-acting check valve 10 preferably has a membrane and / or a spring. In addition, it is designed so that it automatically opens at a pressure drop threshold between 10 mbar and 200 mbar, preferably between 100 mbar and 200 mbar, in particular at 150 mbar. The passively operating check valve 10 is thus not electronically controlled or regulated, but is quasi controlled only by the fluid flow. The opening and closing thus depends only on the fluid flow or the pressure generated by the fluid flow.

The main line 4 is in the embodiment shown a supply line for supplying an oxidant to the fuel cell 2, wherein the main line 4 is coupled in this embodiment with the supply air of the humidifier 6. In addition, the main line 4 is connected to an actively operating valve 11, which is designed as a shut-off valve. The actively operating valve 11 is arranged in the main line 4 after the branch 8 and in front of the humidifier 6.

The device 3 is designed such that the oxidant acted upon by the compressor 5 at a flow rate flows in the main line 4 and / or in the bypass line 7. For this purpose, the bypass line 7 is designed so that depending on an operating state of the fuel cell device 1 at least a certain proportion of this oxidant is passed through the bypass line 7 to the humidifier 6 around, in this regard, the valves 10 and 11 are set accordingly.

At the above-mentioned pressure loss threshold, the passive check valve 10 automatically opens so that oxidant is passed around the humidifier 6 through the bypass line 7. In particular, in operating phases in which the fuel cell device 1 is started up (start-up phase), or in a phase in which the fuel cell device 1 is shut down (shut-down phase), the humidity of the media supplied to the fuel cell 2 must be less than be in a normal operation to prevent condensation or freezing of water in the fuel cell 2 can. In these cases, the actively operating valve 11 is closed according driven. The oxidant now flows exclusively and completely through the bypass line 7 and thus around the humidifier 6 and is again introduced at the junction 9 into the main line 4 in front of the fuel cell 2.

In addition to the main line 4 shown in FIG. 1, which is formed there as a supply line for supplying a reaction medium to the fuel cell 2, the device 3 may also have a discharge line for discharging a medium discharged from the fuel cell 2, in particular exhaust gas. This discharge line is then preferably also from the fuel cell 2 coming through the humidifier 6, in particular its exhaust side out.

In Fig. 2, a further embodiment is shown in which, in contrast to the embodiment in Fig. 1, the bypass line 7 is formed completely valve-free. This means that no valve, in particular no passively operating valve 10, is arranged in the bypass line 7. In contrast, in this embodiment in FIG. 2, it is provided that a passively operating valve 10 is arranged in the main line 4. In particular, it is provided that this passively operating valve 10 in the Main line 4, which in the embodiment shown is also the supply line for supplying an oxidant to the fuel cell 2, is arranged between the branch 8 and the humidifier 6.

In both embodiments according to FIG. 1 and FIG. 2, it may additionally be provided that a device for adjusting a pressure loss at the humidifier 6 is provided in the bypass line 7. This device may include a throttle or orifice or another valve. By this additional device, the respective amounts of air flow through the bypass line 7 and the humidifier 6 the given pressure losses of the humidifier 6 can be better adapted.

FIG. 3 shows a further exemplary embodiment of a fuel cell device 1. Again, the fuel cell device 1 comprises at least one fuel cell 2, the compressor 5, a supply line 4 for supplying oxidant from the compressor 5 via the humidifier 6 to the cathode compartment of the fuel cell 2. In particular, this supply line 4 of the device 3 is assigned. In addition, the device 3 comprises a discharge line designed as a main line 12 for discharging the exhaust gas flowing out of the fuel cell 2. From this main line or discharge line 12 branches off a bypass line 13 at the junction 14 in front of the humidifier 6 and flows into this discharge line 12 at the junction 15 after the humidifier 6 again. The exhaust gas emerging from the fuel cell 2 is thus routed to the humidifier 6 via the discharge line 12 through the humidifier 6 or at least partially via the bypass line 13 as required. In the exemplary embodiment shown in FIG. 3, a passively operating valve, which is designed as a passively functioning check valve 10, is arranged in the bypass line 13. Furthermore, it is provided that an actively operating valve 11, which is designed as a shut-off valve and is electronically controlled, is arranged in the discharge line 12 after the branch 14 in front of the humidifier 6. With regard to the design of the valves 10 and 11, reference is made to the statements relating to FIGS. 1 and 2, since an analogous configuration is provided in particular in this respect.

The amounts of gas flowing through the humidifier 6 and through the bypass or the bypass line 7 to bypass the humidifier 6 depend on the respective pressure losses of the humidifier 6 and the bypass line 7. Below a pressure drop threshold, ie at relatively low flow velocities of the medium in the lines 4 and 12, the exhaust gas exiting from the fuel cell 2 is passed completely around the humidifier 6 through the bypass line 7. This is in particular in the case of the so-called start-up and the shut-down of the fuel cell device 1, the case in which the fuel cell 2 is operated with lower power and thus lower air volume.

FIG. 4 shows an exemplary embodiment of a fuel cell device 1, in which, in contrast to the embodiment in FIG. 3, the passive check valve 10 is arranged in the discharge line 12 and, in particular, between the branch 14 and the humidifier 6. In addition, the bypass line 13 is valve-free.

In addition, in the embodiments according to FIGS. 3 and 4, similar to the embodiments according to FIGS. 1 and 2, it may be provided that a pressure loss adjusting device, for example in the form of a throttle valve or an orifice or another valve, is formed in the bypass line 7.

In all embodiments, at least one passively operating valve 10 is thus used, which is arranged instead of control valves used in the known fuel cell systems in the bypass line 7 or 13 or in a supply line 4 or in a discharge line 12.

LIST OF REFERENCE NUMBERS

1 fuel cell device

2 fuel cell

3 device

4 main line

5 compressor

6 humidifiers

7 bypass line

8 junction g junction

10 passive check valve

11 active working valve

12 main line

13 bypass

14 diversion

15 junction

Claims

claims

A fuel cell device comprising at least one fuel cell (2) and a device (3) for supplying a reaction medium for and discharging purge medium from the fuel cell (2), and a humidifier (6) connected to the device (3) and the fuel cell (2), characterized in that the device (3) has a bypass line (7, 13) which branches off in the flow direction of one of the media in front of the humidifier (6) from a main line (4, 12) of the device (3) , and a passively operating valve (10) in the bypass line (7, 13) and / or a passively operating valve (10) in the main line (4, 12) is arranged.

2. Fuel cell device according to claim 1, characterized in that the passively operating valve is a check valve (10).

3. Fuel cell device according to claim 1 or 2, characterized in that the passively operating valve (10) at a pressure drop threshold between 10 mbar and 200 mbar, preferably between 100 mbar and 200 mbar, particularly preferably at 150 mbar, automatically opens.

4. Fuel cell device according to one of the preceding claims, characterized in that in the bypass line (7, 13) the passively operating valve (10) is arranged and in the main line (4, 12) an actively operating valve (11), in particular an e - Lektronisch controlled shut-off valve is arranged.

5. Fuel cell device according to claim 4, characterized in that the actively operating valve (11) in the main line after the branch (8, 14) of the bypass line (7, 13) of the main line (4, 12) and in front of the humidifier (6 ) is arranged.

6. Fuel cell device according to one of claims 1 to 3, characterized in that the passively operating valve (10) in the main line (4, 12) is arranged and the bypass line (7, 13) is valve-free.

7. Fuel cell device according to claim 6, characterized in that the passively operating valve (10) after the branch (8, 14) of the bypass line (7, 13) of the main line (4, 12) and in front of the humidifier (6) is arranged ,

8. Fuel cell device according to one of the preceding claims, characterized in that the bypass line (7, 13) after the humidifier (6) in the main line (4, 12) opens.

9. Fuel cell device according to one of the preceding claims, characterized in that the main line is a feed line (4) for supplying a reaction medium to the fuel cell (2).

10. Fuel cell device according to one of claims 1 to 8, characterized in that the main line (4, 12) is a discharge line (12) for discharging exhaust gas from the fuel cell (2).

11. Fuel cell device according to one of the preceding claims, characterized in that in the bypass line (7, 13) a means for adjusting a pressure loss at the humidifier (6) is arranged.

12. Fuel cell device according to claim 11, characterized in that the device comprises a throttle valve or a diaphragm or a further valve.

13. Fuel cell device according to one of the preceding claims, characterized in that the main line (4, 12) is connected to the cathode space of the fuel cell (2).

14. Fuel cell device according to one of the preceding claims, characterized in that a delivery unit, in particular a compressor (5), upstream of the branch (8, 14) of the bypass line (7, 13) from the main line (4, 12) with the main line ( 4, 12) is connected.

15. A method for operating a fuel cell device (1) with at least one fuel cell (2) and a device (3), with which a reaction medium supplied to the fuel cell (2) and a discharge medium from the fuel cell (2) removed and the reaction medium and / or the purge medium is passed through a humidifier (6) connected to a main conduit (4, 12) of the apparatus (3), the apparatus (3) comprising a bypass conduit (7, 13) extending downstream from one of the media before the humidifier (6) is branched off from the main line (4, 12) of the device (3), and a passively operating valve (10) in the bypass line (7, 13) and / or a passively operating valve (10) in the Main line (4, 12) is arranged, which is opened depending on a Ll- exceed a pressure drop threshold.