DE102022209491A1 - Fuel cell system and method for operating a fuel cell system - Google Patents

Abstract

The invention relates to a fuel cell system (1) with a first fuel cell stack (100) and at least one second fuel cell stack (200), the first and the at least one second fuel cell stack (100, 200) each having a cathode (110, 210) and an anode ( 120, 220), wherein the cathodes (110, 210) are each connected on the inlet side to a supply air path (111, 211) and on the outlet side to an exhaust air path (112, 212), and wherein the anodes (120, 220) are each connected to an anode circuit (121, 221) are connected. The exhaust air path (112) of the first fuel cell stack (100) and the exhaust air path (212) of the at least one second fuel cell stack (200) are connected to a common exhaust air line (301), which has an outlet into the environment (303). The invention relates to this In addition, a method for operating such a fuel cell system (1).

Description

The invention relates to a fuel cell system. The invention further relates to a method for operating a fuel cell system.

State of the art

Hydrogen-based fuel cell systems are considered the mobility concept of the future because they only emit water as exhaust gas and enable quick refueling times. Fuel cell systems require air and hydrogen for the chemical reaction within the fuel cells. To provide the required amount of energy, the fuel cells arranged within a fuel cell system are interconnected to form so-called fuel cell stacks. The waste heat from the fuel cells is dissipated using a cooling circuit and released into the environment. The hydrogen required to operate fuel cell systems is usually provided to the systems from high-pressure tanks.

In vehicles with fuel cells, the hydrogen in the hydrogen supply system is recirculated in an anode circuit according to the state of the art. Nitrogen, water and other impurities accumulate in the closed circuit during operation. These contaminants must be removed from the circuit. For this purpose, the gas mixture is released continuously or discontinuously via a purge valve and replaced with hydrogen.

Hydrogen also escapes in various concentrations. In the presence of oxygen, flammable mixtures can then form. If the gas mixture from the hydrogen cycle is mixed with the cathode exhaust air, for example, the concentration of hydrogen can be reduced to the legally prescribed limits.

The document DE 10 2006 013 699 A1 shows a fuel cell system with a fuel cell and an actuating element actuated by a control unit for releasing residual gas from a fuel flow of the fuel cell.

In fuel cell systems with several fuel cell stacks, each fuel cell stack has its own exhaust air path, in each of which a hydrogen sensor is arranged. The hydrogen sensor checks that the prescribed limit values for the hydrogen concentration in the gas mixture of the exhaust air path, which is led into the environment, is not exceeded.

Disclosure of the invention

The fuel cell system according to the invention and the method for operating a fuel cell system with the features according to the independent claims have the advantage that in fuel cell systems with several fuel cell stacks, the hydrogen concentration in the exhaust air that enters the environment is not exceeded.

In the solution known from the prior art, a hydrogen sensor must be installed in each exhaust gas path, which continuously measures the proportion of hydrogen in the exhaust gas path, so that measures can be taken if necessary to avoid an excessively high concentration of hydrogen.

In the fuel cell system according to the invention with at least two fuel cell stacks, there is only one hydrogen sensor in the fuel cell system, which is designed to measure the hydrogen concentration in the exhaust gas. There is no need for a hydrogen sensor assigned to the fuel cell stack and arranged in the exhaust air path of the individual fuel cell stack. Instead, the hydrogen sensor for the entire fuel cell system is located in a common exhaust pipe. The exhaust gas from the exhaust gas paths of the individual fuel cells is collected in the common exhaust air line before it flows into the environment. The exhaust air paths of the individual fuel cell stacks are connected to the common exhaust air line.

This means that the number of hydrogen sensors can be greatly reduced and costs can be saved.

The method according to the invention coordinates the control of the different purge valves so that a release for opening a purge valve only occurs when all other purge valves of the fuel cell system are closed. If there are only two fuel cell stacks in the fuel cell system, the purge valve of the first fuel cell stack is released when the purge valve of the second fuel cell stack is closed. Analogously, a release for opening the purge valve of the second fuel cell stack occurs when the purge valve of the first fuel cell stack is closed.

In this way, the level of flow through the individual purge valves can be increased because the total exhaust air mass flow from all exhaust gas paths is used for dilution. The time for a purge process around the recirculation circuit Emptying the anode of a fuel cell stack of unwanted gases can therefore be shortened.

Due to the higher amounts of exhaust air that are available for diluting the hydrogen from the purge line due to the common exhaust air line, the formation of an ignitable mixture can be better avoided.

Safe operation of the fuel cell system can be guaranteed in any operating state.

Advantageous refinements and developments of the fuel cell system according to the invention and the method for operating a fuel cell system are specified in the dependent claims.

It is advantageous that the exhaust air path of the first fuel cell stack and the exhaust air path of the at least one second fuel cell stack are connected to the common exhaust air line via a collector, since this ensures better mixing of the exhaust gas from the different exhaust air paths.

A particular advantage is achieved if the collector is designed in such a way that it ensures mixing of the exhaust air from the exhaust air path of the first fuel cell stack and the exhaust air from the at least one second fuel cell stack, for example by means of vortex elements, ribs or a spiral structure arranged inside.

A hydrogen sensor in the common fuel line is advantageous because the hydrogen concentration in the entire exhaust gas from all exhaust gas paths can be determined before the exhaust gas enters the environment.

It is advantageous if the first purge line of the first fuel cell stack connects the anode circuit with the exhaust air path of the first fuel cell stack and if a purge line of the at least one second fuel cell stack connects the anode circuit with the exhaust air path of the at least one second fuel cell stack, since the gases from the purge line is mixed evenly with the exhaust air from all fuel cell stacks by the collector.

An arrangement in which the purge line of the first fuel cell stack connects the anode circuit of the first fuel cell stack to the common exhaust air line and the purge line of the at least one second fuel cell stack connects the anode circuit of the at least one further fuel cell stack to the common exhaust air line is advantageous because the gases from The anode circuit can be introduced in front of the hydrogen sensor so that they can be better detected by the hydrogen sensor. For this reason, the purge line of the first fuel cell stack and the purge line of the at least one second fuel cell stack should open into the common exhaust air line in front of the hydrogen sensor.

It is advantageous if the opening and closing of the purge valves of the first fuel cell stack and the at least one second fuel cell stack are coordinated by a central control device or several decentralized control devices in such a way that a maximum of one purge valve is opened.

A particular advantage arises if the purge valve in the fuel cell system, which is assigned to the fuel cell stack with the highest nitrogen concentration in the anode circuit, is opened first, as this counteracts a reduction in the overall performance of the fuel cell system and damage to the respective fuel cell stack.

• 1 eine schematische Darstellung einer Topologie eines Brennstoffzellensystems gemäß eines ersten Ausführungsbeispiels und
• 2 eine schematische Darstellung einer Topologie eines Brennstoffzellensystems gemäß eines zweiten Ausführungsbeispiels.

The invention is explained in more detail below with reference to the accompanying drawing. These show:

• 1 a schematic representation of a topology of a fuel cell system according to a first exemplary embodiment and
• 2 a schematic representation of a topology of a fuel cell system according to a second exemplary embodiment.

Detailed description of the drawings

1 shows a fuel cell system 1 according to the invention with a first fuel cell stack 100 and a second fuel cell stack 200 according to a first exemplary embodiment of the invention.

The first fuel cell stack 100 has a cathode 110 and an anode 120. The cathode 110 is supplied with air as an oxygen supplier via a supply air path 111. The air is taken from the environment and may be supplied to the cathode 110 via air filters and an air compression system to provide a certain air mass flow and pressure level.

The exhaust air from the fuel cell stack 100 is removed via an exhaust air path 112.

The anode 120 is circulated with fresh anode gas or hydrogen via a fuel line 115 and with recirculated via an anode circuit 121 Anode gas supplied. The recirculation in the anode circuit 121 can be effected passively with the aid of a jet pump 124 and/or actively with the aid of a blower 123. Since the recirculated anode gas enriches with nitrogen over time, which diffuses from the side of the cathode 110 to the side of the anode 120, the anode circuit 121 is connected to a purge line 133 in which a purge valve 122 is arranged. By opening the purge valve 122, nitrogen-containing anode gas is removed from the anode circuit 121.

The purge line 133 of the first fuel cell stack 100 connects the anode circuit 121 with the exhaust air path 112 of the first fuel cell stack 100. By opening the purge valve 122, nitrogen-containing anode gas is passed from the anode circuit 121 into the exhaust air path 112 and from there discharged into the environment.

The heat generated during operation of the fuel cell stack 100 can be dissipated using a cooling circuit.

The second fuel cell stack 200 has a cathode 210 and an anode 220. The cathode 210 is supplied with air as an oxygen supplier via a supply air path 211. The air is taken from the environment and may be supplied to the cathode 210 via air filters and an air compression system to provide a certain air mass flow and pressure level.

The exhaust air from the fuel cell stack 200 is removed via an exhaust air path 212.

The anode 220 is supplied with fresh anode gas or hydrogen via a fuel line 215 and with recirculated anode gas via an anode circuit 221. The recirculation of the anode circuit 221 can be effected passively with the aid of a jet pump 224 and/or actively with the aid of a blower 223. Since the recirculated anode gas enriches with nitrogen over time and diffuses from the side of the cathode 210 to the side of the anode 220, the anode circuit 221 is connected to a purge line 233 in which a purge valve 222 is arranged.

The purge line 233 of the second fuel cell stack 200 connects the anode circuit 221 to the exhaust air path 212 of the second fuel cell stack 200. By opening the purge valve 222, nitrogen-containing anode gas is passed from the anode circuit 221 into the exhaust air path 212 and from there discharged into the environment.

In addition to the two fuel cell stacks 100, 200 shown, the fuel cell system 1 can also have further fuel cell stacks whose line system is constructed analogously.

The exhaust air path 112 of the first fuel cell stack 100 and the exhaust air path 212 of the at least one second fuel cell stack 200 are connected to a common exhaust air line 301, which has an exit 303 into the environment.

In an optional embodiment, the exhaust air path 112 of the first fuel cell stack 100 and the exhaust air path 212 of the at least one second fuel cell stack 200 can be connected to the common exhaust air line 301 via a collector 304. Since the collector 304 is an optional component, it is in the 1 shown by dashed lines.

The collector 304 can be designed so that it ensures mixing of the exhaust air from the exhaust air path 112 of the first fuel cell stack 100 and the exhaust air from the exhaust air path 212 of the second fuel cell stack 200. This can be achieved with the help of vortex elements, such as ribs or a spiral structure, as these internals promote turbulent air flow.

A hydrogen sensor 302 is arranged in the common exhaust air line 301, which can measure the hydrogen concentration in the common hydrogen line 301.

The opening and closing of the purge valves 112, 222 is controlled via a central control device 400, which can communicate with the two purge valves 112, 222 wirelessly or by cable.

2 shows a fuel cell system 1 according to the invention with a first fuel cell stack 100 and a second fuel cell stack 200 according to a second exemplary embodiment of the invention.

The fuel cell system 1 is constructed like the fuel cell system 1 according to the first exemplary embodiment, except for the differences described below.

The purge line 133 of the first fuel cell stack 100 connects the anode circuit 121 with the common exhaust air line 301. By opening the purge valve 122, nitrogen-containing anode gas is passed from the anode circuit 121 of the first fuel cell stack 100 into the common exhaust air line 301 and from there discharged into the environment via an outlet 303 .

The purge line 233 of the second fuel cell stack 200 connects the anode circuit 221 with the common exhaust air line 301. By opening the purge valve 222, nitrogen-containing anode gas is passed from the anode circuit 221 of the second fuel cell stack 200 into the common exhaust air line 301 and from there discharged into the environment via an outlet 303 .

The purge line 133 of the first fuel cell stack 100 and the purge line 233 of the at least one second fuel cell stack 200 open into the common exhaust air line 301 in front of the hydrogen sensor 302.

The opening and closing of the purge valves 112, 222 is controlled via several decentralized control devices 401, 402 that can communicate with one another. Here, the first control device 401 is assigned to the purge valve 122 of the first fuel cell stack 100 and the second control device 401 is assigned to the purge valve 222 of the second fuel cell stack 100. Alternatively, a central control device for opening and closing the purge valves is also possible.

According to the method according to the invention for operating a fuel cell system 1 according to the exemplary embodiments described above, a release for opening the purge valve 122 of the first fuel cell stack 100 takes place when the purge valve 222 of the at least one second fuel cell stack 200 is closed. Accordingly, a release for opening the purge valve 222 of the at least one second fuel cell stack 200 occurs when the purge valve 122 of the first fuel cell stack 100 is closed.

A central control device 400 or several decentralized control devices 401, 402, which communicate with one another, can coordinate the opening and closing of the purge valves 122, 222 of the first fuel cell stack 100 and the at least one second fuel cell stack 200 so that a maximum of one purge valve 122, 222 is opened.

If all purge valves 122, 222 are closed, the purge valve 122, 222 which has the highest nitrogen concentration in the respective anode circuit 121, 221 is opened first.

The fuel cell system 1 can have a water container in the anode circuit 121 of the first fuel cell stack 100, which is connected to the purge line 133 of the first fuel cell stack 100 via a drain valve. Analogously, there can be a water container in the anode circuit 221 of the second fuel cell stack 200, which is connected to the purge line 233 of the second fuel cell stack 200 via a drain valve.

A release to open the drain valve of the first fuel cell stack 100 occurs when the drain valve of the at least one second fuel cell stack 200 is closed and a release to open the drain valve of the at least one second fuel cell stack 200 occurs when the drain valve of the first fuel cell stack 200 is closed.

QUOTES INCLUDED IN THE DESCRIPTION

This list of 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.

Cited patent literature

• DE 102006013699 A1 [0005]

Claims (11)

Fuel cell system (1) with a first fuel cell stack (100, 200) and at least one second fuel cell stack (200), the first and the at least one second fuel cell stack (200) each having a cathode (110, 210) and an anode (120, 220). have, wherein the cathodes (110, 210) are each connected on the inlet side to a supply air path (111, 211) and on the outlet side to an exhaust air path (112, 212), and wherein the anodes (120, 220) are each connected to an anode circuit (121, 221 ) are connected, characterized in that the exhaust air path (112) of the first fuel cell stack (100) and the exhaust air path of the at least one second fuel cell stack (200) are connected to a common exhaust air line (301), which has an outlet (303) into the environment . fuel cell system Claim 1 , characterized in that the exhaust air path (112) of the first fuel cell stack (100) and the exhaust air path (212) of the at least one second fuel cell stack (200) are connected to the common exhaust air line (301) via a collector (304). fuel cell system Claim 2 , characterized in that the collector (304) is designed such that it ensures mixing of the exhaust air from the exhaust air path (112) of the first fuel cell stack (100) and the exhaust air of the at least one second fuel cell stack (200). Fuel cell system according to one of the preceding claims, characterized in that the common fuel line (301) has a hydrogen sensor (302). Fuel cell system according to one of the preceding claims, characterized in that a first purge line (133) of the first fuel cell stack (100) connects the anode circuit (121) with the exhaust air path (112) of the first fuel cell stack (100) and that a purge line (233) of the at least one second fuel cell stack (200), which connects the anode circuit (221) to the exhaust air path (212) of the at least one second fuel cell stack (200). Fuel cell system according to one of the preceding claims, characterized in that a purge line (133) of the first fuel cell stack (100) connects the anode circuit (121) of the first fuel cell stack (100) with the common exhaust air line (301) and that a purge line (233) of the at least one second fuel cell stack (200), which connects the anode circuit (221) of the at least one second fuel cell stack (200) to the common exhaust air line (301). fuel cell system Claim 6 , characterized in that the purge line (133) of the first fuel cell stack (100) and the purge line (233) of the at least one second fuel cell stack (200) open into the common exhaust air line (301) in front of the hydrogen sensor (302). Fuel cell system according to one of the Claims 5 until 7 , characterized in that the purge line (133) of the first fuel cell stack (100) and the purge line (233) of the at least one second fuel cell stack (200) each have a purge valve (122, 222). Method for operating a fuel cell system Claim 8 , characterized in that a release to open the purge valve (122) of the first fuel cell stack (100) occurs when the purge valve (222) of the at least one second fuel cell stack (200) is closed and a release to open the purge valve (222) of the at least a second fuel cell stack (200) occurs when the purge valve (122) of the first fuel cell stack (200) is closed. Procedure according to Claim 9 , characterized in that a central control device or several decentralized control devices, which can communicate with one another, coordinate or coordinate the opening and closing of the purge valves (122, 222) of the first fuel cell stack (100) and the at least one second fuel cell stack (200), that a maximum of one purge valve (122, 222) is open. Procedure according to Claim 9 or 10 , characterized in that the purge valve (122, 222) is opened first, which is assigned to the fuel cell stack (100,200) which has the highest nitrogen concentration in the respective anode circuit (121, 221).

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