WO2023148135A2 - Power supply device - Google Patents

Abstract

The invention relates to a power supply device (1) having a plurality of fuel cell units (12) arranged in parallel strands (50, 60, 70), wherein each strand (50, 60, 70) has at least two fuel cell units (12) connected in series or at least two groups (13, 13'), connected in series, of fuel cell units (12). According to the invention, the strands (50, 60, 70) are interconnected in each case at a node point by means of at least one cross connector (90, 90', 90'', 90'''), wherein the node points (92, 92') are formed between two fuel cell units (12), connected in series, of a strand (50, 60, 70) or between two groups (13, 13') of fuel cell units (12) of a strand (50, 60, 70).

Description

Description

title

The invention relates to an energy supply device.

State of the art

In order to enable greater power, it is known to connect several fuel cell units together. It is known to connect the fuel cell units together electrically in strings. It is also known that the strands are electrically connected to one another in parallel. If one of the fuel cell units fails or there are problems, this can lead to the failure of an entire train.

Disclosure of Invention

The invention relates to an energy supply device with a plurality of fuel cell units arranged in parallel lines, each line having at least two fuel cell units or two groups of fuel cell units. It is advantageous that the strands are each connected to one another at a node via at least one cross-connector. Furthermore, it is advantageous that the junction points are formed between two fuel cell units of a train connected in series or between two groups of fuel cell units of a train. A fuel cell unit is in series with at least one other fuel cell unit and in parallel with at least one other fuel cell unit interconnected. Alternatively, a single group of fuel cell units is connected in series with at least one further group of fuel cell units and in parallel with at least one further group of fuel cell units. Problems of individual fuel cell units or groups of fuel cell units can advantageously be compensated for. There is no failure of the entire energy supply device or larger parts of the energy supply device.

The measures listed in the subclaims result in advantageous developments and improvements of the energy supply device specified in the main claim.

An advantageous further development is that the fuel cell units or groups of fuel cell units are connected to one another in parallel and in series in the manner of a matrix. The result is an interconnection corresponding to a matrix.

As an advantageous development, it has been shown that fuses or electrical switches are formed in the cross-connectors. The function of the electrical cross-connector can advantageously be activated or deactivated. At the same time, fuses are a simple way of preventing destruction in the event of a fault.

An advantageous development is that at least one, in particular all, of the fuses are in the form of bonding wires. Such a fuse is a simple and inexpensive way to secure the power supply system and its components.

As an advantageous development, it has been shown that at least one group of fuel cell units has at least two fuel cell units that are connected in parallel and/or in series. Flexibility can advantageously be increased and the risk of failure reduced. An advantageous development is that at least one group of fuel cell units or at least one fuel cell unit has a serially arranged voltage converter, in particular a DC/DC converter. The voltages can advantageously be adjusted in this way.

An advantageous further development is that each cross-connector connects two nodes of two strands to one another.

It has been shown as an advantageous further development that the groups of fuel cell units, which are in particular connected in parallel to one another, each have an identical number of fuel cell units.

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

Figure lein schematic circuit diagram of an embodiment of a fuel cell device;

FIG. 2 shows schematically the electrical wiring of an energy supply device according to one embodiment;

FIG. 3 schematically shows the electrical wiring of an energy supply device according to a further development; and

FIG. 4 shows the process sequence of a method for regulating the fuel cell units.

In the following, descriptions of the elements with a reference number without an apostrophe also always refer to the elements with one or more apostrophes.

The invention relates to an energy supply device 1. The energy supply device 1 comprises at least one Fuel cell device 10 and a plurality of fuel cell units 12. FIG. 1 shows the structure of a fuel cell device 10 by way of example. FIG. 2 shows the structure of an energy supply device 1 with six fuel cell units 12 as an example. FIG. 3 shows the structure of an energy supply device 1 with six groups of fuel cell units 12 as an example. Figures 2 and 3 are simplified in that only the electrical paths are shown schematically. It goes without saying that the energy supply device 1 shown in FIGS. 2 and 3 also has additional processor units 14 in addition to the fuel cell units 12 . The processor units 14 are described in more detail below in FIG. As described below, the fuel cell units 12 and the processor units 14 can be arbitrarily combined to form the fuel cell device 10 . Also, a fuel cell device 10 can form a group of fuel cell units.

1 shows a schematic circuit diagram of an exemplary embodiment of a fuel cell device 10 . The fuel cell device 10 comprises, for example, two fuel cell units 12. Preferably, more than the two fuel cell units 12 shown in FIG. 1 can be formed.

In the exemplary embodiment shown, the fuel cell units 12 are designed as fuel cell stacks which have a multiplicity of fuel cells, in the present case solid oxide fuel cells (SOFC).

Furthermore, the fuel cell device 10 includes a large number of processor units 14. The number and scaling of the processor units 14 depends on the number of fuel cell units 12 and on the design and structure of the entire energy supply device 1.

In the context of this invention, a “processor unit” 14 is intended in particular to mean a unit or component of the fuel cell device 10 or the Energy supply device 1 can be understood, which is not a fuel cell unit 12 . In the present case, the processor units 14 are units for the chemical and/or thermal preparation and/or post-processing of at least one medium to be converted and/or converted in a fuel cell unit 12, such as an oxidation medium, in particular air and/or oxygen, and/or an exhaust gas and/or a fuel, preferably a combustible gas, in particular natural gas or hydrogen.

One of the processor units 14 is a heat exchanger 18 arranged in an air supply 16 for heating an oxidizing medium, in particular air L containing oxygen, supplied to the fuel cell units 12. In the present case, the oxidizing medium, in particular the air L, for example in normal operation, is one Supplied to the cathode space 20 of the fuel cell units 12, while in each case an anode space 22 is supplied with reformed fuel RB, in this case hydrogen or natural gas. In the fuel cell units 12, the reformed fuel RB is electrochemically converted by the participation of oxygen from the air L, with the generation of electricity and heat. Electrical energy is generated.

The reformed fuel RB is generated by fuel B, in particular natural gas or hydrogen or methane or coal gas, being supplied to the fuel cell device 10 via a fuel supply 24, which fuel is reformed in a further processor unit 14, in the present case a reformer 26.

Furthermore, the fuel cell units 12 are connected on the exhaust gas side to a further processor unit 14 , in the present case to an afterburner 28 . Exhaust gas from the fuel cell units 12 is supplied to the afterburner 28, in the present case cathode exhaust gas KA via a cathode exhaust gas duct 30 and part of the anode exhaust gas AA via an anode exhaust gas duct 32. The cathode exhaust gas KA contains unused oxidation medium, in particular air L or unused oxygen. while the anode off-gas AA may contain unreacted, reformed fuel RB and/or possibly non-reformed fuel B. By means of the afterburner 28, the anode waste gas AA, or any unreacted, reformed fuel RB contained therein and/or the non-reformed fuel B contained therein, is mixed with the cathode waste gas KA, or the oxygen contained therein Oxidizing medium, in particular the air L, burned, whereby additional heat can be generated.

The hot exhaust gas A produced during the combustion in the afterburner 28 is discharged from the afterburner 28 via an exhaust gas duct 34 via a further processor unit 14, in the present case via a heat exchanger 36. The heat exchanger 36 is in turn fluidically connected to the reformer 26 so that heat is transferred from the hot exhaust gas A to the fuel B supplied to the reformer 26 . Accordingly, the heat of the hot exhaust gas A can be used for reforming the fuel B supplied in the reformer 26 .

A further processor unit 14, in the present case the heat exchanger 18, is located downstream of the heat exchanger 36 in the exhaust gas duct 34, so that the remaining heat of the hot exhaust gas A can be transferred to the supplied oxidation medium, in particular air L in the air supply 16. Correspondingly, the remaining heat of the hot exhaust gas can be used for preheating the supplied oxidation medium, in particular the air L in the air duct 16 .

In addition, the fuel cell device 10 has a return 38 by means of which part of the anode exhaust gas AA can be branched off from the anode exhaust gas line 32 and fed to an anode recirculation circuit 40 . The anode waste gas AA that is branched off passes through a further processor unit 14, in the present case a further heat exchanger 39.

By means of the anode recirculation circuit 40, the branched-off part of the anode waste gas AA can be returned or fed back to the respective anode space 22 of the fuel cell units 12 and/or the reformer 26, see above that the unreacted, reformed fuel RB possibly contained in the branched off anode waste gas AA can subsequently be converted in the fuel cell unit 12 and/or the unreformed fuel B possibly contained in the branched off anode waste gas AA can subsequently be reformed in the reformer 26. As a result, the efficiency of the fuel cell device 10 can be further increased. In addition, fresh fuel B can be admixed via the fuel feed line 24 to the anode exhaust gas AA that has been branched off and recirculated in the anode recirculation circuit 40 . By means of the additional heat exchanger

39 heat can then be transferred from the branched off anode waste gas AA from the return line 38 to the fuel mixture produced by the admixture of the fresh fuel B in the anode recirculation circuit 40 for thermal treatment.

About compressor 42 in the respective lines, the supply of an oxidizing medium, in particular of oxidizing media, preferably air L in the air supply 16, the supply of fuel B in the fuel supply 24 and the recirculation rate of the anode exhaust gas AA in the anode recirculation circuit

40 regulated and/or coordinated.

The fuel cell device preferably has a heating element 44 for, in the present case additional, heating of the oxidation medium supplied to the fuel cell units 12, in particular air L in a bypass line 46, as a result of which the operating efficiency of the fuel cell device 10 is increased.

The invention is not limited to solid oxide fuel cells. Rather, any fuel cells can be designed. For example, the fuel cells can also be classified as alkaline fuel cell (AFC), low temperature polymer electrolyte fuel cell (NT-PEMFC), high temperature polymer electrolyte membrane fuel cell (HT-PEMFC), direct methanol fuel cell (DMFC), phosphoric acid fuel cell (PAFC), molten carbonate Fuel cell (MCFC) be running. The fuels used or the oxidizing medium differ accordingly. Examples of fuels are hydrogen, alcohols (ethanol, propanol, glycerine, methanol), methane, coal gas, ammonia reformate gas, especially methanol. Examples of oxidation media are air, in particular the atmospheric oxygen in the air, oxygen, hydrogen peroxide, nitric acid or halogens.

The process units 14 are adapted depending on the fuel cell used in the fuel cell unit 12 .

The electrical wiring of an energy supply device 1 is shown schematically in FIG. The energy supply device 1 has, for example, three strands 50, 60, 70, each with two fuel cell units 12. The number of fuel cell units 12 is not limited to two per line. The fuel cell units 12 of a train 50, 60, 70 are connected to one another in series here, for example.

The strands 50, 60, 70 are electrically connected in parallel to one another. According to the invention, any number of strands 50, 60, 70 can be selected. The number of fuel cell units 12 per strand can also be selected as desired.

According to a first embodiment, the fuel cell units 12 of a train 50, 60, 70 form a fuel cell device 10. Accordingly, one fuel cell device 10 per train, ie three fuel cell devices 10, are shown in FIG.

Contrary to the example in FIG. 1, a fuel cell device 10 can also have more or fewer than the two fuel cell units 12 indicated in FIG. Correspondingly, the processor units 14 required by a fuel cell unit are adapted in terms of number, power and dimensions. Each fuel cell unit 12 preferably requires a large number of processor units 14 as shown in FIG.

Individual processor units 14 can be designed and set up in such a way that they share a number of fuel cell units 12 . For example 1 shows two fuel cell units 12 and a large number of processor units 14 for supplying them.

According to a further development, individual processor units 14 can supply several fuel cell units 12 at the same time. A single processor unit 14 can also supply fuel cell units 12 from more than one line 50 , 60 , 70 . In particular, a compressor 42 can be provided for two or more fuel cell units 12 . The air supply 16 can also be used for many, in particular all, fuel cell units 12 .

The strands 50, 60, 70 are connected to one another via at least one cross-connector 90. Three cross-connectors 90′, 90″, 90″ are embodied as an example. The cross-connectors 90 connect two strands 50, 60, 70 each at one of the node points 92, which are formed between two serially arranged fuel cell units 12.

In particular, the cross-connector 90' connects a node 92 of the first line 50 to a node 92 of the second line 60. The cross-connector 90' connects the first line 50 to the second line 60. In particular, the cross-connector 90" connects a node 92 of the second line 60 to a node 92 of the third line 70. The cross-connector 90" connects the second line 60 to the third line 70. In particular, the cross-connector 90''" connects a node 92 of the third line 70 to a node 92 of the first line 50. The cross-connector 90 ''' connects the third strand 70 to the first strand 50. In particular, the cross-connector 90''' is optional. The cross-connector 90'' is particularly necessary when the cross-connector 90 has a component. The cross-connector 90 establishes an electrical connection between two nodes 92, in particular strands 50, 60, 70.

A matrix-like parallel and serial connection of the fuel cell units 12 preferably results. If one of the fuel cell units 12 falls, in particular due to maintenance, damage, aging, the energy supply device 1 can nevertheless continue to provide energy.

According to a development, at least one of the cross-connectors 90 has an additional electrical component 82 or an electrical circuit. In particular, the electrical component 82 can be in the form of a fuse, switch, diode or converter, preferably a voltage converter, or a combination thereof. A fuse and a diode or a fuse and a switch would preferably be possible.

A diode would have to be installed in such a way that it opens in the desired direction of current flow and blocks in the opposite current direction.

The fuse can preferably be designed as a bond fuse. The switch can be designed in particular as a thyristor, relay, contactor, pyro switch or semiconductor switch, in particular a transistor, preferably a field effect transistor, for example MosFet, JFet or bipolar transistor. It is also conceivable that a combination of different switches or fuses mentioned is formed. A parallel connection of several semiconductor switches, transistors, field effect transistors, MosFets, JFets or bipolar transistors is also conceivable. The electrical component is advantageously formed in all cross-connectors that would have the same potential without the electrical component. In particular, all cross-connectors that result in two fuel cell units 12 being connected in parallel.

According to a development, some or all strands 50, 60, 70 have at least one electrical component 80. A component 80 is preferably assigned to at least one fuel cell unit 12 . In particular, each fuel cell unit 12 is assigned a component 80 . The fuel cell unit 12 and the associated component 80 are in particular connected in series with one another. At least one electrical component is preferably formed between at least one, in particular all, nodes 92 (including nodes 92′) of a strand 50, 60, 70.

The component 80 can be designed in particular as a fuse, switch, diode or converter. Inequalities between the fuel cell units can thus preferably be compensated for. Such inequalities occur, for example, when there are minimal temperature differences in the fuel cell units during start-up or shut-down operation. The inequalities lead in particular to different current strengths in the individual strands.

Training as a converter has the disadvantage that the converters are more expensive. The use of converters also means the use of additional components, which can form additional sources of error.

The fuse can preferably be designed as a bond fuse. The switch can be designed in particular as a thyristor or semiconductor switch, preferably MosFet.

The component 80 can preferably be in the form of a diode, semiconductor switch or relay. In the warm-up phase and the cool-down phase of the energy supply device 1, the individual fuel cell units 12 generally have different voltages and internal resistances. The reason for this is that the warm-up or cool-down process is usually not completely synchronous. The result of this is that the voltage of the fuel cell units 12 would differ from the voltage of a fuel cell unit 12 connected in parallel in the case of a non-parallel connection. However, since the voltage in parallel circuits is always the same without any interruption at 80 or 82, equalizing currents flow which can lead to damage, in particular cell oxidation or unwanted aging, of the fuel cell units 12. Current is prevented from flowing into the fuel cell units 12 in the reverse direction than it actually does is provided. The components 80 designed as diodes or corresponding switches, relays, thyristors, MosFets or the like prevent the flow of such compensating currents.

According to an advantageous development, the components 80 are each designed as voltage converters, in particular DC/DC converters. According to an advantageous development, at least one electrical component 80 per row can be omitted.

It is advantageous that by installing, for example, relays, thyristors, semiconductor switches, field effect transistors, in particular MosFets, or bipolar transistors or diodes at the position of component 80, it can be prevented in a simple manner that, in particular during normal operation and/or start-up operation and/or Shutdown operation, a defect, in particular an internal short circuit in the fuel cell units, reduction in the active anode or cathode area, reduction in the cell voltage generated, imbalance between the fuel cell units, increase in the internal resistance in a fuel cell unit 12 to a negative influence on those connected electrically in parallel

Fuel cell units 12 leads. In addition, different performances can be compensated for when driving off and/or when driving off.

An advantageous development is that a control unit is provided which controls the components 80 . In particular, the control can take place as a function of detected defects or errors. Such faults or defects are, for example, a short circuit within the fuel cell unit, a reduction in the active anode or cathode area, a reduction in the cell voltage generated, an increase in the internal resistance.

In particular, the control unit can be designed, in particular continuously, to perform scenario calculations that check whether it makes sense to switch off individual strands 50, 60, 70 or fuel cell units 12 or groups of fuel cell units 12 according to one or more of the following criteria. A first criterion is that maximization the total electrical output of the entire energy supply device 1. A further criterion is the achievement of maximum efficiency, in particular with a predetermined target output. A further criterion is the achievement of maximum efficiency, in particular with a specified target output. Another criterion is the achievement of minimal aging, in particular individually for each fuel cell unit 12. Another criterion is the fulfillment of specifications (grid codes) for a rapid load change, in particular one or more fuel cell units 12 in partial load, in a specified time to enable a power increase or power reduction. Another criterion is continued operation of the system when a fuel cell unit 12 is deactivated.

As already explained, the electrical component 80 and/or 82 can be designed as a switch, in particular an electrical switch, preferably a semiconductor switch, for example a transistor. This allows the individual fuel cell units 12 to be electrically isolated between two nodes 92 . This has no direct effects on the other fuel cell unit 12.

When viewed mathematically, the energy supply device 1 according to FIG. 2 has two rows and 3 columns. The columns correspond to the strands. The rows are at the same voltage when there is a cross connector 90 but without an electrical component 82 thereon.

A further embodiment is shown in FIG. In contrast to the embodiment according to FIG. 2, individual fuel cell units 12 are replaced by groups 13 of fuel cell units 12 .

In particular, each group 13 of fuel cell units 12 has two fuel cell units 12 by way of example. Each group 13 of fuel cell unit 12 could preferably form a fuel cell device 10 . Each group 13 of fuel cell units 12 can preferably also have more than two fuel cell units 12 .

The groups 13' of fuel cell units 12 of the first row are connected to one another in series, for example. The fuel cell unit 12 of the group 13' of fuel cell unit 12 and the optional component 80 are connected in series between two nodes 92.

The groups 13″ of fuel cell unit 12 of the second row are connected to one another in parallel, for example. The fuel cell unit 12 of the group 13 ″ of the fuel cell unit 12 and the optional component 80 are connected in series between two nodes 92 .

A mixed, ie parallel and serial, connection is preferably also conceivable. At least four or more fuel cell units 12 per group 13 are preferably necessary for this purpose.

According to an advantageous development, individual fuel cell units 12 can be regulated in such a way that the current and voltage occurring between two nodes 92 are adjusted to the fuel cell units 12 connected in parallel. Such a rule is also referred to below as regulation.

Processor units 14, which are used for regulation, are preferably designed separately for the individual fuel cell units 12 or groups of fuel cell units 12 to be regulated.

The regulation 120 preferably takes place by appropriate activation 122 of a processor unit 14, in particular of a plurality of processor units 14. The method 100 and its method steps are explained in detail in FIG.

In the case of an electrically parallel connection according to FIG. 2, there is a forced equalization of the voltage between the nodes 92, 92'. A Forced voltage equalization can lead to an asymmetrical current distribution, in particular due to aging and/or temperature differences and/or manufacturing tolerances between the fuel cell units 12.

The current that develops depends on the internal resistance of the fuel cell units 12 . The internal resistance depends, for example, on the temperature of the fuel cell unit 12, the aging of the fuel cell unit 12, the oxidation medium supplied and the fuel supplied.

In particular, fuel cell units 12 with many locally adjacent fuel cell units 12 are additionally heated by them. A warmer fuel cell unit 12 has lower thermal losses. Also, when heated, the fuel cell unit 12 has a low internal resistance. The low internal resistance leads to an increased current, which in turn leads to an increased temperature. A spiral can ensue.

An optional converter 98 is implemented in the exemplary embodiments according to FIGS. This is preferably a DC/AC voltage converter, which converts the direct voltage generated by the fuel cell unit 12 into alternating voltage. In particular, the public power grids and most consumers work with an AC voltage.

A further voltage converter 96 is preferably connected upstream of the optional converter 98 . The voltage converter 96 is a DC/DC converter. The further voltage converter 96 can be omitted if the components 80 themselves are in the form of voltage converters, in particular DC/DC converters. The voltage converter 96 is necessary in particular because a defined minimum voltage level is always required upstream of a DC/AC converter 98, so that the DC/AC converter 98 can convert 98 reasonably and efficiently into alternating current. The voltage converter 96 and additionally or alternatively the voltage converters that are formed at position 80 generate an intermediate circuit voltage 97 with a minimum necessary voltage level, so that the voltage converter 98 can work sensibly and/or efficiently.

An advantageous further development is that the voltage converters 96 and 98 are combined in one device. Advantageously, cost and installation space optimization can be achieved in this way. There is also a lower probability of failure due to a small number of individual components.

All components 80 are preferably of identical design. All components 82 are preferably of identical design. In particular, the components 80 and 82 can also have differences, but these are based on the fuel cell units 12 with which they are connected in series or in parallel.

A method 100 according to the invention is shown in FIG.

In a first method step 110, the current flowing between two nodes is determined. All streams are preferably determined.

The determination 110 takes place in particular by measuring individual currents. The currents that were not measured can then be calculated from the measured currents as part of the determination.

The currents are preferably determined using a shunt resistor. In particular, the shunt resistor can be arranged according to component 80 . The shunt resistor is arranged in series with the fuel cell unit or units 12 or the group of fuel cell units 12 .

In a further method step 120, at least one fuel cell unit 12, in particular a plurality of fuel cell units 12, preferably all fuel cell units 12, is regulated.

Regulating 120 includes changing, in particular increasing or reducing, the supply of a fuel and/or the supply of a fuel Oxidation medium and / or the heating of the supplied oxidizing medium and / or the heating of the fuel and / or the recirculation rate in the fuel cell unit to be regulated. By regulating 120, a change in the current is achieved. In this case, the fuel cell units 12 react more sensitively to a change in the supply of fuel than to a change in the oxidation medium and/or the recirculation rate.

Each fuel cell unit 12 is preferably regulated individually. Groups 13 of fuel cell units 12 are preferably regulated. The fuel cell units 12 are preferably regulated jointly between two nodes 92, 92'.

For example, by means of a compressor 42 in the air supply 16, the supply of air L can be regulated. A compressor 42 in the fuel supply 24 can regulate the supply of fuel B. A compressor 42 in the anode recirculation circuit 40 can regulate the recirculation rate of the anode exhaust gas AA. In method step 120, depending on the string currents determined in method step 110, individual or multiple fuel cell units 12 are regulated.

The regulation 120 in method step 120 preferably takes place in such a way that the streams adjust to one another. In particular, after regulation 120, the currents are negligibly different. Preferably, after regulation, the flows are substantially equal.

In an optional method step 122, individual or multiple processor units 14 are activated. The activation 122 is a sub-method step of method step 120. In an optional method step 116, the fuel cell units 12, which are regulated in method step 120, are selected. Preferably, the fuel cell units 12 are selected that have a current that deviates from the other currents by a tolerance.

According to an advantageous development, the aging of individual fuel cell units 12 can also be determined. The selection 116 is then also made based on the aging of the fuel cell units 12.

Furthermore, the selection 116 can be made depending on the position of the fuel cell unit 12 relative to other fuel cell units 12 . In particular, fuel cell units 12 that have many adjacent fuel cell units 12 tend to be warmer and thereby have a lower internal resistance.

The fuel cell units 12 to be regulated are preferably selected whose determined currents deviate from a defined target current.

The target current is preferably defined. Alternatively or additionally, the setpoint current is determined from the total current. To do this, the total current is divided by the number of strands 50, 60, 70.

Claims

Claims Energy supply device (1), with a plurality of fuel cell units (12) arranged in parallel strings (50, 60, 70), each string (50, 60, 70) having at least two fuel cell units (12) connected in series or at least two in series connected groups (13, 13') of fuel cell units (12), characterized in that the strands (50, 60, 70) are each connected to one node via at least one cross-connector (90, 90', 90", 90"") to one another are connected, the nodes (92, 92') between two series-connected fuel cell units (12) of a train (50, 60, 70) or between two groups (13, 13') of fuel cell units (12) of a train (50, 60, 70) are formed. Energy supply device (1) according to the preceding claim, characterized in that the fuel cell units (12) or groups (13, 13') of fuel cell units (12) are connected to one another in parallel and in series in the manner of a matrix. Energy supply device (1) according to one of the preceding claims, characterized in that fuses or electrical switches are formed in the cross-connectors (90, 90', 90", 90'"). Energy supply device (1) according to one of the preceding claims, characterized in that at least one, in particular all, fuses are designed as bonding wires. Energy supply device (1) according to one of the preceding claims, characterized in that at least one group (13, 13', 13") of fuel cell units (12) has at least two fuel cell units (12) which are connected in parallel and/or in series.

6. Energy supply device (1) according to one of the preceding claims, characterized in that at least one group (13, 13', 13") of fuel cell units (12) or at least one fuel cell unit (12) has a serially arranged voltage converter, in particular a DC/DC converter having.

7. Energy supply device (1) according to one of the preceding claims, characterized in that each cross-connector (90, 90', 90", 90'") has two nodes (92, 92') of two strands (50, 60, 70) with one another connects. 8. Energy supply device (1) according to one of the preceding claims, characterized in that the groups (13, 13', 13") of fuel cell units (12), in particular those connected in parallel to one another, each have an identical number of fuel cell units (12).