DE102019206701A1 - Fuel cell device and method for operating such a fuel cell device - Google Patents

Abstract

The invention relates to a fuel cell device (10) and a method for operating such a fuel cell device (10), comprising a reformer (22) which is provided to reform a fuel mixture for a fuel cell (12), a heat exchanger (26) in a Feed line (28) to the reformer (22) is arranged. It is proposed to form a bypass (44) to bypass the heat exchanger (26).

Description

The present invention relates to a fuel cell device comprising a reformer which is provided to reform a fuel mixture for a fuel cell, a heat exchanger being arranged in a feed line to the reformer. The invention also relates to a method for operating such a fuel cell device.

State of the art

The document WO 2010/044772 A1 discloses a fuel cell device with a reformer, which is provided to reform a fuel mixture for a fuel cell, a heat exchanger being arranged in a feed line to the reformer. The heat exchanger in the feed line to the reformer keeps a temperature of a reformed fuel mixture at the outlet of the reformer at a temperature required for the electrochemical conversion in the fuel cell.

Disclosure of the invention

The present invention with the features of the main claim has the advantage that a bypass is designed to bypass the heat exchanger. This enables the temperature of a reformed fuel mixture at the outlet of a reformer to be regulated, which in turn enables the efficiency of the fuel cell device to be increased.

In the context of this invention, the term “bypass” can in particular be understood to mean a fluidic bridging. It can preferably be understood as a fluidic bridging which at least partially diverts a medium from a media line at one point and feeds it back to the media line at another point.

In the context of this invention, the phrase “to bypass the heat exchanger” can in particular be understood to mean that a medium is at least partially flowed past the heat exchanger. This should preferably be understood to mean that a medium which is transported through a media line which is connected to the heat exchanger is at least partially guided past the heat exchanger in terms of flow. Particularly preferably, this can be understood to mean that a medium from which heat can be transferred by means of the heat exchanger to the fuel mixture to be reformed is at least partially routed past the heat exchanger in terms of flow.

The features listed in the subclaims allow advantageous developments of the invention according to the main claim. It is therefore advantageous if an afterburner is connected to at least one exhaust gas line of the fuel cell, whereby the thermal integration within the fuel cell device can be simplified.

In an advantageous embodiment, the heat exchanger is connected to an outlet of the afterburner. As a result, heat generated in the afterburner can be used effectively for reforming.

It is particularly advantageous if the afterburner has a direct fuel feed and / or air feed. This enables additional control of the heat transfer to the fuel mixture to be reformed. Accordingly, the efficiency of the fuel cell device can also be increased and a robust operation can be ensured.

In a further advantageous embodiment, the heat exchanger is connected to an air electrode exhaust line of the fuel cell. As a result, heat generated in the fuel cell can be effectively used for reforming.

In a further advantageous embodiment, the heat exchanger is connected to a fuel electrode exhaust line. As a result, heat generated in the fuel cell can also be used effectively for reforming.

In a further advantageous embodiment, the heat exchanger is connected to an air electrode supply line of the fuel cell, whereby heat that may have been transferred to air in the air electrode supply line can also be used effectively for the reforming.

The invention also relates to a method for operating a fuel cell device, in particular a fuel cell device according to the preceding description, comprising a reformer, which is provided to reform a fuel mixture for a fuel cell, a heat exchanger being arranged in a feed line to the reformer. The method has the advantage that the heat exchanger is bypassed by means of a bypass. This enables the temperature of a reformed fuel mixture at the outlet of a reformer to be regulated, which in turn enables the efficiency of the fuel cell device to be increased.

It is particularly advantageous if the temperature of a reformed fuel mixture at the outlet of the reformer is reduced by bypassing the heat exchanger by means of the bypass. In this way, the temperature of the reformed fuel mixture at the outlet of the reformer can be regulated particularly efficiently, and robust operation can be ensured.

In an advantageous embodiment of the method, an afterburner is connected to at least one exhaust gas line of the fuel cell, which is fed with fuel by means of a direct fuel feed and / or with air by means of a direct air feed. This enables an additional regulation of the temperature of a reformed fuel mixture at the outlet of the reformer, which in turn can additionally increase the efficiency of the fuel cell device.

It is particularly advantageous if the temperature of a reformed fuel mixture at the outlet of the reformer is increased by feeding in fuel by means of the direct fuel feed and / or air by means of the direct air feed. A particularly efficient control and / or regulation of the temperature of the reformed fuel mixture at the outlet of the reformer can thus also take place.

Figure list

• 1 eine schematische Darstellung eines Ausführungsbeispiels einer Brennstoffzellenvorrichtung,
• 2 eine schematische Darstellung eines weiteren Ausführungsbeispiels einer Brennstoffzellenvorrichtung,
• 3 eine schematische Darstellung eines weiteren Ausführungsbeispiels einer Brennstoffzellenvorrichtung,
• 4 eine schematische Darstellung eines weiteren Ausführungsbeispiels einer Brennstoffzellenvorrichtung,
• 5 eine schematische Darstellung eines weiteren Ausführungsbeispiels einer Brennstoffzellenvorrichtung,

In the drawings, exemplary embodiments of the invention are shown schematically and explained in more detail in the description below. Show it

• 1 a schematic representation of an embodiment of a fuel cell device,
• 2 a schematic representation of a further embodiment of a fuel cell device,
• 3 a schematic representation of a further embodiment of a fuel cell device,
• 4th a schematic representation of a further embodiment of a fuel cell device,
• 5 a schematic representation of a further embodiment of a fuel cell device,

Description of the exemplary embodiments

The figures show schematic representations of various exemplary embodiments of the fuel cell device according to the invention 10 shown. The fuel cell devices shown 10 each include a fuel cell 12 , in the present cases each a SOFC fuel cell, by means of which both electricity and heat can be generated.

The respective fuel cells 12 each have two electrodes 14th , one anode each in the cases shown 16 and a cathode 18th , as well as an electrolyte arranged in between 20th on. Alternatively, however, it would also be possible for the fuel cell devices shown 10 each a fuel cell stack with a plurality of fuel cells 12 exhibit.

The fuel cell devices shown also include 10 one reformer each 22nd , which is provided for a fuel mixture for the fuel cell 12 to reform. The reformer 22nd is connected to a fuel electrode lead 24 the fuel cell 12 connected.

In the cases shown, the fuel cell devices 10 operated in such a way that via a fuel supply line 30th a fuel mixture, in the present cases natural gas, and parallel to it via an air supply line 32 Air is supplied. The amount of the supplied fuel mixture and the supplied air is via compressor 34 , 38 , or blower 36 , 40 , regulated. The air then becomes the cathode 18th the fuel cell 12 via an air electrode lead 42 fed, while the fuel mixture is initially the reformer 22nd is fed where it is for use in the fuel cell 12 is reformed and then the anode 16 the fuel cell 12 via the fuel electrode lead 24 is fed. In the cases shown, the reformed fuel mixture is hydrogen-containing synthesis gas which is in the fuel cell 12 is converted electrochemically with the generation of electricity and heat.

When reforming in the reformer 22nd In the present cases, it is an endothermic reaction which would normally result in the temperature (e.g. approx. 500 ° C) of the reformed fuel mixture at the outlet of the reformer being lower than the temperature (e.g. approx. 700 ° C) ) for the optimal electrochemical conversion in the fuel cell 12 would be required. In the present cases, however, is a heat exchanger 26th in a supply line 28 to the reformer 22nd arranged. Through the heat exchanger 26th , the temperature of the fuel mixture to be reformed is increased in advance, which means that the reformed fuel mixture or the hydrogen-containing synthesis gas at the outlet of the reformer 22nd , in the fuel electrode lead 24 the fuel cell 12 , one for the electrochemical conversion in the Fuel cell 12 required, higher temperature. Accordingly, the reformer 22nd also as passively heated and / or isenthalpic reformer 22nd be understood, since the heat transfer to the fuel mixture and the actual reforming take place in two separate reaction chambers.

Usually, electrical heating elements, such as heating wires, are used, which can be arranged relatively easily in a feed line to the reformer for heating a fuel cell mixture to be reformed. Such electrical heating wires have the advantage that they are easy to control, which means that the temperature can also be regulated accordingly. However, it is disadvantageous that such heating elements usually have a high energy consumption.

The present fuel cell devices 10 is now characterized by the fact that each has a bypass 44 to bypass the heat exchanger 26th is trained. This enables the heat transfer to be regulated to the fuel mixture to be reformed, which also increases the temperature of the reformed fuel mixture at the outlet of the reformer 22nd , in the fuel electrode lead 24 the fuel cell 12 , for the electrochemical conversion in the fuel cell 12 can be regulated. The efficiency of the respective fuel cell device can thereby be correspondingly increased 10 increase.

In 1 Figure 3 is a schematic representation of an embodiment of a fuel cell device 10 shown. In the embodiment shown, there is an afterburner 46 on both exhaust pipes 48 , in the case shown on a fuel electrode exhaust line 50 and on an air electrode exhaust line 52 , the fuel cell 12 connected. Through the afterburner, among other things, in the fuel cell 12 non-electrochemically converted fuel with the addition of the fuel in the fuel cell 12 unused air can be subsequently burned, whereby additional heat can be generated. Accordingly, the efficiency of the fuel cell device can be increased 10 can be increased.

The heat exchanger 26th is at one output of the afterburner 46 connected. In the case shown is the heat exchanger 26th in an exhaust pipe 54 of the afterburner 46 connected. The heat exchanger 26th is in this way at the outlet of the afterburner 46 connected that heat from the exhaust of the afterburner 46 , or heat from the one in the exhaust pipe 54 transported exhaust gas of the afterburner 46 , on the fuel mixture to be reformed or that in the supply line 28 to the reformer 22nd transported fuel mixture, is transferable.

The bypass 44 is now designed in such a way that the exhaust gas from the afterburner 46 upstream of the heat exchanger 26th at least partially from the exhaust pipe 54 of the afterburner 46 can be removed and downstream of the heat exchanger 26th again the exhaust pipe 54 of the afterburner 46 is feedable. So can the exhaust gas from the afterburner 46 on the heat exchanger 26th at least partially bypassed, whereby a heat transfer from the exhaust gas of the afterburner 46 on the fuel mixture to be reformed in the feed line 28 of the reformer 22nd can be specifically prevented. So can bypass 44 a reduction in the heat transfer to the fuel mixture to be reformed can be carried out and, as a result, also a reduction in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd respectively.

The afterburner 46 has a direct fuel feed 56 on. The fuel feed 56 is designed in such a way that at least part of the fuel mixture supplied comes from the fuel supply line 30th the afterburner 46 is fed directly. This can cause combustion in the afterburner 46 can also be regulated, which in turn increases the temperature of the exhaust gas from the afterburner 46 can be regulated and increased if necessary. So can by means of the direct fuel feed 56 an improved regulation and possibly an increase in the heat transfer to the fuel mixture to be reformed take place and, as a result, an improved regulation and possibly an increase in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd .

Using the bypass 44 to bypass the heat exchanger, it is therefore possible to regulate the temperature of the reformed fuel mixture at the outlet of the reformer 22nd take place towards lower temperatures, while by means of the fuel feed 56 a regulation of the temperature of the reformed fuel mixture at the outlet of the reformer 22nd can take place towards higher temperatures.

In 2 Fig. 3 is a schematic representation of another embodiment of a fuel cell device 10 shown. The embodiment shown differs from that in FIG 1 embodiment shown is that the afterburner 46 only on one of the two exhaust pipes 48 , in the case shown only on the fuel electrode exhaust line 50 , the fuel cell 12 connected. The air electrode exhaust line 52 opens into the exhaust pipe in the case shown 54 of the afterburner 46 .

Also, it differs in 2 shown embodiment of the in 1 embodiment shown is that the afterburner 46 in addition to the direct fuel feed 56 also a direct air supply 58 having. The air supply 58 is designed in such a way that at least part of the air supplied comes from the air supply line 30th the afterburner 46 is fed directly. This can cause combustion in the afterburner 46 can be regulated via the fuel-air ratio fed in, which in turn allows a temperature of the exhaust gas from the afterburner to be better regulated and, if necessary, increased. So can by means of the direct fuel feed 56 an improved regulation and possibly an increase in the heat transfer to the fuel mixture to be reformed take place and, as a result, an improved regulation and possibly an increase in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd .

Alternatively, it would also be possible for the afterburner 46 only a direct air supply 58 has, ie no direct fuel feed 56 has, causing combustion in the afterburner 48 could also be at least partially regulated.

In any case, the bypass can be used 44 a regulation of the temperature of the reformed fuel mixture at the outlet of the reformer to bypass the heat exchanger 22nd take place towards lower temperatures, while by means of the fuel feed 56 and / or the air supply 58 a regulation of the temperature of the reformed fuel mixture at the outlet of the reformer 22nd can take place towards higher temperatures.

In 3 Fig. 3 is a schematic representation of another embodiment of a fuel cell device 10 shown. This in 3 The embodiment shown differs from that in 1 embodiment shown is that the heat exchanger 26th on the air electrode exhaust line 52 the fuel cell 12 connected. The bypass 44 again is designed in such a way that the cathode exhaust gas from the fuel cell 12 upstream of the heat exchanger 26th at least partially from the air electrode exhaust line 52 the fuel cell 12 can be removed and downstream of the heat exchanger 26th again the air electrode exhaust line 52 the fuel cell 12 is feedable. So can the cathode exhaust gas of the fuel cell 12 on the heat exchanger 26th at least partially bypassed, whereby a heat transfer from the cathode exhaust gas of the fuel cell 12 on the fuel mixture to be reformed in the feed line 28 of the reformer 22nd can be specifically prevented. Correspondingly, by means of the bypass 44 a reduction in the heat transfer to the fuel mixture to be reformed can be carried out and, as a result, also a reduction in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd respectively.

In 4th Fig. 3 is a schematic representation of another embodiment of a fuel cell device 10 shown. This in 4th The embodiment shown differs from that in 1 embodiment shown is that the heat exchanger 26th on the fuel electrode exhaust line 50 the fuel cell 12 connected. The bypass 44 again is designed in such a way that the anode exhaust gas from the fuel cell 12 upstream of the heat exchanger 26th at least partially from the fuel electrode exhaust line 50 the fuel cell 12 can be removed and downstream of the heat exchanger 26th again the fuel electrode exhaust line 50 the fuel cell 12 is feedable. So can the anode exhaust gas of the fuel cell 12 on the heat exchanger 26th at least partially bypassed, whereby a heat transfer from the cathode exhaust gas of the fuel cell 12 on the fuel mixture to be reformed in the feed line 28 of the reformer 22nd can be specifically prevented. Correspondingly, by means of the bypass 44 a reduction in the heat transfer to the fuel mixture to be reformed can be carried out and, as a result, also a reduction in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd respectively.

In all shown exemplary embodiments of the fuel cell device 10 is another heat exchanger 60 in the air supply line 42 arranged, which at the output of the heat exchanger 26th ( 1 , 2 ) or the outlet of the afterburner 46 ( 3-5 ) connected. Through this there is a heat transfer from the exhaust gas of the afterburner 46 on the air supplied in the air electrode supply line 42 allows the air supplied to operate in the fuel cell 12 can be preheated. Alternatively, however, it would also be conceivable instead of the additional heat exchanger 60 in the air electrode lead 42 to arrange an electrical heating element through which the air for operation in the fuel cell 12 can be preheated.

In 5 Fig. 3 is a schematic representation of another embodiment of a fuel cell device 10 shown. The additional heat exchanger is also in this exemplary embodiment 60 in the air electrode lead 42 arranged, which at the outlet of the afterburner 46 connected. In contrast to the in 1 The embodiment shown is in the in 5 shown embodiment of the heat exchanger 26th downstream of the further heat exchanger 60 at the Air electrode lead 42 the fuel cell 12 connected. This allows heat to be transferred from the exhaust gas of the afterburner 46 on the air in the air electrode lead 42 and then by means of the heat exchanger 26th in the supply line 28 of the reformer 22nd on the fuel mixture to be reformed, creating the heat for the reforming in the reformer 22nd can be used. The bypass 44 in turn, it is designed in such a way that the preheated air is upstream of the heat exchanger 26th at least partially from the air electrode supply line 42 the fuel cell 12 can be removed and downstream of the heat exchanger 26th again that of the air electrode lead 42 the fuel cell 12 is feedable. This allows the preheated air to pass through the heat exchanger 26th at least partially bypassed, whereby a heat transfer from the preheated air in the air electrode supply line 42 on the fuel mixture to be reformed in the feed line 28 of the reformer 22nd can be specifically prevented. Correspondingly, by means of the bypass 44 a reduction in the heat transfer to the fuel mixture to be reformed can be carried out and, as a result, also a reduction in the temperature of the reformed fuel mixture at the outlet of the reformer 22nd . In the embodiment shown, the afterburner is used 46 , as in 4th , to the air electrode exhaust line 52 connected.

In addition, in all the exemplary embodiments shown, at least part of the anode exhaust of the fuel cell 12 via a recirculation line 62 recirculated. Thus, the efficiency of the fuel cell device is increased. The recirculation line 62 is arranged in such a way that at least part of the anode exhaust gas is upstream of the afterburner 46 from the fuel electrode exhaust line 50 is discharged and upstream of the heat exchanger 26th the supply line 28 of the reformer 22nd is fed. Via a recirculation compressor 64 , in the cases shown, a recirculation fan 66 , the amount of recirculated anode exhaust gas is regulated.

In all of the exemplary embodiments shown, it is also possible for actively heated reformers to be used in addition.

QUOTES INCLUDED IN THE DESCRIPTION

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

Patent literature cited

• WO 2010/044772 A1 [0002]

Claims (11)

Fuel cell device (10) comprising a reformer (22), which is provided to reform a fuel mixture for a fuel cell (12), a heat exchanger (26) being arranged in a feed line (28) to the reformer (22), characterized by a bypass (44) to bypass the heat exchanger (26). Fuel cell device (10) according to Claim 1 , characterized in that an afterburner (46) is connected to at least one exhaust pipe (48) of the fuel cell (12). Fuel cell device (10) according to one of the Claims 2 , characterized in that the heat exchanger (26) is connected to an output of an afterburner (46). Fuel cell device (10) according to Claim 2 or 3 , characterized in that the afterburner (46) has a direct fuel feed (56) and / or air feed (58). Fuel cell device (10) according to one of the preceding claims, characterized in that the heat exchanger (26) is connected to an air electrode exhaust line (52) of the fuel cell (12). Fuel cell device (10) according to one of the preceding claims, characterized in that the heat exchanger (26) is connected to a fuel electrode exhaust line (50). Fuel cell device (10) according to one of the preceding claims, characterized in that the heat exchanger (26) is connected to an air electrode feed line (42) of the fuel cell (12). A method for operating a fuel cell device (10), in particular a fuel cell device (10) according to one of the preceding claims, comprising a reformer (22), which is provided to reform a fuel mixture for a fuel cell (12), a heat exchanger (26) in a supply line (28) to the reformer (22), characterized in that the heat exchanger (26) is bypassed by means of a bypass (44). Procedure according to Claim 8 , characterized in that the temperature of a reformed fuel mixture at the outlet of the reformer (22) is reduced by bypassing the heat exchanger by means of the bypass (44). Method according to one of the Claims 8 or 9 , characterized in that an afterburner (46) is connected to at least one exhaust line (48) of the fuel cell (12), which is fed with fuel by means of a direct fuel feed (56) and / or with air by means of a direct air feed (58). Procedure according to Claim 10 , characterized in that the temperature of a reformed fuel mixture at the outlet of the reformer (22) is increased by feeding in fuel by means of the direct fuel feed (56) and / or air by means of the direct air feed (58).

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