DE102021204643A1 - Fuel cell system without energy recuperation and a method for operating such a fuel cell system - Google Patents

Abstract

The invention relates to a fuel cell system (100), having at least one fuel cell (101) and a cathode system (10) for providing an oxygen-containing reactant in the form of supply air (L1) to the at least one fuel cell (101), the cathode system (10) having a air supply line (11) for providing the supply air (L1) to the at least one fuel cell (101) and an exhaust air line (12) for discharging an exhaust air (L2) from the at least one fuel cell (101), the cathode system (10) being designed without recuperation and wherein at least one heat exchanger (20) is provided between the supply air line (11) and the exhaust air line (12) of the cathode system (10), which is designed to passively transfer thermal energy from the supply air (L1) to the exhaust air (L2). transferred to.

Description

The invention relates to a fuel cell system without energy recuperation in an exhaust air line of a cathode system according to the preamble of the independent device claim. Furthermore, the invention relates to a method for operating a fuel cell system according to the preamble of the independent method claim.

State of the art

In drive systems with fuel cell systems i. i.e. R. Oxygen from the ambient air is used to react with hydrogen in a fuel cell to form water or water vapor and thus generate electrical energy. The ambient air is to be supplied to the fuel cell stack by means of an air conveying system or air compression system. This requires a corresponding air mass flow and a corresponding pressure level. If higher operating pressures are required in the cathode system, e.g. to achieve high power densities, this is associated with a correspondingly increased effort in air compression. This leads to increased temperatures of the compressed air in the cathode system. The compressed air must be cooled in order to comply with the maximum permissible inlet temperatures into the fuel cell or into an optionally available humidifier, if available. The removal of heat from the air system increases the demands on the cooling system.

Disclosure of Invention

According to a first aspect, the invention provides a fuel cell system with the features of the independent device claim, in particular from the characterizing part. Furthermore, according to a second aspect, the invention provides a method for operating a fuel cell system with the features of the independent method claim, in particular from the characterizing part. Further advantages, features and details of the invention result from the dependent claims, the description and the drawings. Features and details that are described in connection with the fuel cell system according to the invention naturally also apply in connection with the method according to the invention and vice versa, so that the disclosure of the individual aspects of the invention is or can always be referred to alternately.

According to the first aspect, the present invention provides a fuel cell system comprising at least one fuel cell and a cathode system for providing an oxygen-containing reactant in the form of supply air to the at least one fuel cell, the cathode system having a supply air line for providing the supply air to the at least one fuel cell and a Has an exhaust air line for removing exhaust air from the at least one fuel cell, the cathode system being designed without recuperation, in particular without a turbine, and at least one heat exchanger being provided between the air supply line and the exhaust air line of the cathode system, which heat exchanger is designed to transfer thermal energy or To transfer heat from the supply air to the exhaust air passively, in particular without a drive.

The fuel cell system according to the invention can have at least one or more fuel cell stacks, so-called fuel cell stacks, each with a plurality of stacked repeating units in the form of a plurality of fuel cells, for example PEM fuel cells.

The fuel cell system according to the invention can advantageously be used for mobile applications, such as in motor vehicles, or for stationary applications, such as in generator systems.

In the context of the invention, a passive design of the heat exchanger means that the heat transfer takes place without a drive and therefore without a drive, such as a coolant pump. With the help of the heat exchanger within the scope of the invention, an additional electrically driven heat exchanger for cooling the supply air can be dispensed with. At least the additional electrically driven heat exchanger for cooling the supply air can be made smaller with the help of the heat exchanger within the scope of the invention. In mobile applications, for example in motor vehicles, this advantageously reduces the load on a vehicle cooler.

The heat exchanger according to the invention can be provided as a module. In addition, it is conceivable that the heat exchanger according to the invention is integrated into the cathode system, e.g. B. in a silencer can be provided.

The idea of the invention lies in the heat transfer between the compressed supply air in the supply air line before the at least one fuel cell and the exhaust air in the exhaust air line after the at least one fuel cell by means of a passive heat exchanger, in particular without mass transfer, e.g. in the form of a gas-gas heat exchanger or heat pipes.

The passive heat exchanger according to the invention advantageously requires no additional che integration into the cooling circuit of the end device, e.g. a vehicle or a generator. This gives rise to the advantage that the heat exchanger according to the invention can be easily integrated within the fuel cell system. This also results in a further advantage that the load on the cooling circuit of the end device can be relieved. Furthermore, no additional actuators are required. As a result, installation space can be reduced and the energy and power efficiency of the fuel cell system can be increased.

In addition, it is advantageous that the liquid water droplets in the mostly supersaturated exhaust air can evaporate and/or vaporize with the aid of the heat transfer into the exhaust air. Thus, the exhaust air can be discharged to the environment largely in the form of vapor and thus less irritating or disruptive. The heated exhaust air can also be used for other purposes, e.g. B. for ventilation of fuel-carrying components such. B. stack housing, tank housing, anode housing, etc., for tempering components, etc. In addition, the heat exchanger can be combined with a silencer according to the invention, resulting in a reduction of audible and / or noticeable vibrations in the exhaust gas path leads. In addition, with the aid of the invention, several divided or common heat coupling points can be implemented.

Furthermore, it can be provided in a fuel cell system that the at least one heat exchanger is designed to be drive-free in order to transfer thermal energy from the supply air to the exhaust air without an electrical energy supply. Parasitic energy costs in the fuel cell system can thus be reduced and the efficiency of the fuel cell system can be increased.

Furthermore, it can be provided in a fuel cell system that the at least one heat exchanger is designed to transfer thermal energy from the supply air to the exhaust air indirectly, in particular without material exchange, for example by evaporation and condensation of a working medium. A heat exchanger can thus be provided which allows a high heat flow density using the heat of vaporization of the working medium.

Furthermore, it is conceivable that the at least one heat exchanger has a first chamber and a second chamber that are hermetically sealed and through which the supply air and the exhaust air are routed, and that in particular the at least one heat exchanger has at least one heat pipe or several heat pipes has, in which or in which a working medium is enclosed. In this way, a passive heat exchanger can be implemented according to a heat pipe or thermosiphon principle, which transfers the heat through evaporation and condensation of the working medium. The at least one heat pipe can have an, in particular metallic, vessel with an elongate extension, which hermetically encloses a working medium. As a working medium z. As methanol, water, refrigerant or ammonia are used. The working medium can be partly in the liquid state and partly in the gaseous state. The section of the heat pipe that absorbs energy is called the evaporator. The section of the heat pipe used to dissipate energy is called the condenser. The evaporator can be shorter than or the same length as the condenser. The evaporator is surrounded by the supply air. The exhaust air flows around the condenser. For this purpose, the at least one heat pipe can be accommodated in a housing with a first chamber and a second chamber, the first chamber being hermetically sealed off from the second chamber. The supply air flows through the first chamber, in which the evaporator is arranged. The exhaust air flows through the second chamber, in which the condenser is arranged. In the first chamber, the compressed supply air transfers the heat to the working medium of the heat pipe in the evaporator. The working medium transports this heat to the condenser, which releases this heat to the exhaust air in the second chamber.

In addition, it can be provided in a fuel cell system that the at least one heat exchanger has at least one first pipe and at least one second pipe, which are routed through the at least one heat exchanger and through which the supply air and the exhaust air are routed, and that in particular the at least one Heat exchanger has a closed housing in which a working medium, for example product water, is enclosed. A passive heat exchanger can thus be implemented, which transfers the heat through evaporation and condensation of the working medium. The working medium is recirculated within the heat exchanger. The vapor rises within the heat exchanger, condenses and drips off. The evaporation of the working medium is triggered by the heated supply air. The working medium absorbs the heat from the supply air by evaporating. The condensation of the working medium is triggered by the cooler exhaust air. Through condensation, the steam transfers the heat to the exhaust air. The condensing working medium drips off and collects again in the lower part of the heat exchanger and is again available for evaporation.

In addition, it can be provided in a fuel cell system that the at least one Heat exchanger is designed to transfer thermal energy from the supply air to the exhaust air indirectly, in particular without mass transfer. It is conceivable that the at least one heat exchanger is designed in the form of a gas-gas heat exchanger. In this way, a heat exchanger that is simple in terms of construction and assembly can be provided.

Furthermore, it can be provided in a fuel cell system that a pressure control valve is provided in the exhaust air line. The pressure in the cathode path can be determined with the help of the pressure control valve.

Furthermore, it can be provided in a fuel cell system that the at least one heat exchanger is arranged in front of the pressure control valve in the exhaust air line, viewed in the direction of flow of the exhaust air. A higher pressure level of the exhaust air in the heat exchanger can thus be set. This can increase the heat capacity of the exhaust air. In this way, a smaller pressure drop in the heat exchanger can also be set.

Furthermore, it can be provided in a fuel cell system that the at least one heat exchanger is arranged after the pressure control valve in the exhaust air line, viewed in the direction of flow of the exhaust air. The advantages of arranging the heat exchanger downstream of the pressure control valve include the fact that the pressure control valve can be combined with a bypass valve in one valve block. A combined three-way valve is also conceivable for the pressure control valve with a bypass valve. A combined valve from the pressure control valve and a shut-off valve is also conceivable. Here, the pressure control valve can be designed as a pressure control valve with an additional sealing function. A combined valve block, a combined three-way valve or a pressure control valve with the sealing function can be interconnected more easily, e.g. by being integrated together in the cable harness. If the heat exchanger is arranged downstream of the pressure control valve, it is also possible to combine the heat exchanger with a silencer in the exhaust air line. In addition, when the heat exchanger is arranged downstream of the pressure control valve, it is possible to split the exhaust air.

In addition, it can be provided in a fuel cell system that at least one compressor is arranged in the supply air line. It is conceivable that the at least one compressor can be designed as a single-flow compressor or as a multi-flow compressor or as a multi-stage compressor. A corresponding air mass flow and a corresponding pressure level of the supply air can be set with the aid of a compressor.

In addition, in a fuel cell system it can be provided that the at least one heat exchanger is arranged in the supply air line after a single-flow compressor or after the first stage of a multi-stage compressor or after the second stage of the multi-stage compressor, viewed in the flow direction of the supply air. In this way, the heat exchanger can be connected flexibly in order to be adapted to different installation space requirements and/or the conditions in the system.

Furthermore, it can be provided in a fuel cell system that the at least one heat exchanger has a first heat exchanger and a second heat exchanger. In this way, the efficiency of heat transfer can be increased. It is conceivable that the first heat exchanger can be arranged after the first stage of the multi-stage compressor and the second heat exchanger after the second stage of the multi-stage compressor, viewed in the flow direction of the supply air in the supply air line. It is also conceivable that the first heat exchanger can be arranged before or after the second heat exchanger, viewed in the flow direction of the exhaust air in the exhaust air line. In addition, it is conceivable that the first heat exchanger and the second heat exchanger can have several divided or common heat coupling points. In this way, more flexibility can be achieved when connecting the heat exchanger, especially in connection with a two-stage compressor.

Furthermore, the at least one heat exchanger can have at least one silencer at an outlet for the exhaust air from the exhaust air line into the at least one heat exchanger. Furthermore, it is conceivable that the at least one heat exchanger can have a second silencer at an inlet for the exhaust air from the at least one heat exchanger into the exhaust air line. This can result in advantages with regard to the reduced installation space and the improved functionality as well as noise and vibration insulation in the system.

In a fuel cell system, it can optionally be provided that at least one gas/coolant heat exchanger can be arranged in the supply air line. The gas-refrigerant heat exchanger can support the heat exchanger if necessary.

According to the second aspect, the present invention provides a method for operating a Fuel cell system without energy recuperation in an exhaust air line of a cathode system, having at least one fuel cell and a cathode system for providing an oxygen-containing reactant in the form of supply air to the at least one fuel cell, the cathode system having an air supply line for providing the supply air to the at least one fuel cell and an exhaust air line for Discharging exhaust air from the at least one fuel cell, and wherein the cathode system is designed to be recuperation-free, and wherein at least one heat exchanger is provided between the air supply line and the exhaust air line of the cathode system, which heat exchanger serves to passively transfer thermal energy from the air supply to the exhaust air . The same advantages are achieved with the aid of the method according to the invention as were described above with the aid of the fuel cell system according to the invention. Reference is made in full to these advantages here. The method is particularly suitable for operating a fuel cell system described above and in the claims.

Furthermore, in a method for operating a fuel cell system without energy recuperation in an exhaust air line of a cathode system, it can be provided that the heated exhaust air is used to ventilate fuel-carrying components of the fuel cell system, such as e.g. B. stack housing, tank housing, anode housing o. Ä., And / or for temperature control of components of the fuel cell system and / or a terminal such. B. a vehicle interior, a traction battery, etc., can be used. In this way, the functionality of the fuel cell system can be expanded without energy recuperation.

Preferred embodiments:

• 1 eine schematische Darstellung eines Brennstoffzellensystems mit einem einflutigen oder einem zweiflutigen Verdichter und einem passiven Wärmeübertrager,
• 2 eine schematische Darstellung eines Brennstoffzellensystems mit einem zweistufigen Verdichter und einem passiven Wärmeübertrager,
• 3 eine schematische Darstellung eines Brennstoffzellensystems mit einem zweistufigen Verdichter und einem passiven Wärmeübertrager,
• 4 eine schematische Darstellung eines Brennstoffzellensystems mit einem zweistufigen Verdichter und zwei passiven Wärmeübertragern,
• 5 eine schematische Darstellung eines Brennstoffzellensystems mit einem einflutigen oder einem zweiflutigen Verdichter und einem passiven Wärmeübertrager,
• 6 eine schematische Darstellung eines Brennstoffzellensystems mit einem zweistufigen Verdichter und einem passiven Wärmeübertrager mit einem kombinierten Schalldämpfer,
• 7 eine schematische Darstellung eines Brennstoffzellensystems mit einem zweistufigen Verdichter und zwei passiven Wärmeübertragern, die aufgeteilte Wärmeeinkopplungsstellen aufweisen,
• 8 eine schematische Darstellung eines Brennstoffzellensystems mit einem einflutigen Verdichter und einem passiven Wärmeübertrager mit zwei Schalldämpfern, und
• 9 eine schematische Darstellung eines Brennstoffzellensystems im Sinne der Erfindung mit einem zweistufigen Verdichter und einem Wärmeübertrager, deren erwärmte Abluft für unterschiedliche Verbraucher genutzt wird.

The invention and its developments as well as its advantages are explained in more detail below with reference to drawings. They each show schematically:

• 1 a schematic representation of a fuel cell system with a single-flow or a double-flow compressor and a passive heat exchanger,
• 2 a schematic representation of a fuel cell system with a two-stage compressor and a passive heat exchanger,
• 3 a schematic representation of a fuel cell system with a two-stage compressor and a passive heat exchanger,
• 4 a schematic representation of a fuel cell system with a two-stage compressor and two passive heat exchangers,
• 5 a schematic representation of a fuel cell system with a single-flow or a double-flow compressor and a passive heat exchanger,
• 6 a schematic representation of a fuel cell system with a two-stage compressor and a passive heat exchanger with a combined silencer,
• 7 a schematic representation of a fuel cell system with a two-stage compressor and two passive heat exchangers, which have divided heat coupling points,
• 8th a schematic representation of a fuel cell system with a single-flow compressor and a passive heat exchanger with two silencers, and
• 9 a schematic representation of a fuel cell system according to the invention with a two-stage compressor and a heat exchanger, the heated exhaust air is used for different consumers.

In the different figures, the same parts of the invention are always provided with the same reference numerals, which is why these i. i.e. R. only be described once.

the 1 until 9 each show a fuel cell system 100 within the meaning of the invention, which has the following elements: at least one fuel cell 101 or at least one fuel cell stack and a cathode system 10 for providing an oxygen-containing reactant in the form of supply air to the at least one fuel cell 101. The cathode system 100 has a supply air line 11 for providing the supply air L1 to the at least one fuel cell 101 and an exhaust air line 12 for discharging an exhaust air L2 from the at least one fuel cell 101, e.g. to an environment U. An air filter AF can be provided at the beginning of the supply air line 11 .

In terms of the invention, the cathode system 10 is recuperation-free, i. H. performed without a turbine in the exhaust line 12. For this purpose, it is provided according to the invention that at least one heat exchanger 20 is provided between the air supply line 11 and the exhaust air line 12 of the cathode system 10, which is designed to transfer thermal energy or heat from the air supply L1 to the exhaust air L2 passively, in particular without a drive . Thus, the at least one heat exchanger 20 can also be referred to as the passive heat exchanger 20 within the meaning of the invention.

The fuel cell system 100 can be used for mobile applications, such as in motor vehicles, or for stationary applications, such as in generator systems.

The invention proposes reducing the heat transfer between the compressed supply air L1 in the supply air line 11 before the at least one fuel cell 101 and the exhaust air L2 in the exhaust air line 12 after the at least one fuel cell 101 by means of a passive heat exchanger 20, in particular without mass transfer, e.g. in the form of gas-gas heat exchangers or heat pipes.

The passive heat exchanger 20 does not require any additional integration into the cooling circuit of the end device, for example a vehicle or a generator. The heat exchanger 20 can thus be arranged and connected within the fuel cell system 100 in a simple manner. This can also relieve the cooling circuit of the end device. Furthermore, as a result, the installation space for the fuel cell system 100 can be efficiently utilized. Furthermore, the energy and power efficiency of the fuel cell system 100 can thereby be increased.

A further advantage of the invention lies in the fact that the liquid water droplets in the mostly supersaturated exhaust air L2 can evaporate and/or vaporize with the aid of the heat transfer into the exhaust air L2. The exhaust air L2 can thus be discharged to the environment U largely in the form of vapor and thus in a less irritating and/or disruptive manner.

Like it the 9 also indicates that the heated exhaust air L2 can also be used for other purposes, e.g. B. for ventilation of fuel-carrying components VI, such. B. stack housing, tank housing, anode housing or similar, for tempering components V2, etc.

Like it the 6 and 8th continue to indicate that the heat exchanger can be combined with at least one silencer 23, 24 in the sense of the invention in order to reduce audible and/or perceptible vibrations in the exhaust gas path.

Like it the 7 further indicates that several divided or common heat coupling points or paths can be realized after a first heat exchanger 21 and after a second heat exchanger 22 with the aid of the invention.

Like it in the 1 until 9 is shown schematically, the at least one heat exchanger 20 is designed without a drive in order to transfer thermal energy from the supply air L1 to the exhaust air L2 without an electrical energy supply in order to reduce parasitic energy costs in the fuel cell system and to increase the efficiency of the fuel cell system 100.

In a heat exchanger according to 1 until 9 it is conceivable that thermal energy is transferred from the supply air L1 to the exhaust air L2 indirectly, in particular without material exchange, for example by evaporation and condensation of a working medium.

The at least one heat exchanger 20 can be implemented according to a heat pipe or thermosiphon principle. However, other embodiments of a passive heat exchanger are also conceivable, which work according to the principle of evaporation and condensation of a working medium.

In a heat exchanger 20 according to the 1 until 9 it is conceivable to indirectly transfer thermal energy from the supply air to the exhaust air, in particular without mass transfer. The at least one heat exchanger 20 can advantageously be designed in the form of a gas-gas heat exchanger.

How it from the 1 until 9 As can be seen, a pressure control valve Cvexh can be provided in the exhaust air line 12 .

In the 1 until 4 and 9 is shown as an example, the at least one heat exchanger 20 can be arranged upstream of the pressure control valve Cvexh in the exhaust air line 12 as viewed in the direction of flow of the exhaust air L2. In this way, a higher pressure level of the exhaust air L2 in the heat exchanger 20 can be set. The heat capacity of the exhaust air L2 can be increased as a result. A smaller pressure drop in the heat exchanger 20 can thus also be set.

In the 5 until 8th is again shown, the at least one heat exchanger 20 can be arranged after the pressure control valve Cvexh, seen in the flow direction of the exhaust air L2 in the exhaust air line 12 .

Like it the 5 shows, with the arrangement of the heat exchanger 20 downstream of the pressure control valve Cvexh, the pressure control valve Cvexh can be combined with a bypass valve ByCath in one valve block. A combined three-way valve is also conceivable for the Cvexh pressure control valve with a ByCath bypass valve.

Like it the 8th indicates, in the arrangement of the heat exchanger 20 downstream of the pressure control valve Cvexh, the functionalities of the pressure control valve Cvexh and the functionalities of a shut-off valve SV2 can be combined in one valve. For this purpose, the pressure control valve Cvexh can be designed with a sealing function.

Like it the 6 and 8th indicate that when the heat exchanger 20 is arranged downstream of the pressure control valve Cvexh, a combination of the heat exchanger 20 with at least one silencer 23 or with two switching dampers 23, 24 in the exhaust air line 12 can be implemented.

Like it the 7 shows, with the arrangement of the heat exchanger 20 downstream of the pressure control valve Cvexh, a distribution of the exhaust air L2 to different heat injection points or heat injection paths can be made possible.

Like it in the 1 until 9 is shown schematically, at least one compressor P is arranged in the supply air line in order to suck in the air from the environment U and to provide it in compressed form in the form of supply air L1 to the at least one fuel cell 101 or to the at least one fuel cell stack. How it from the 1 until 9 As can be seen, the at least one compressor P can be designed as a single-flow compressor P, as a multi-flow compressor PP or as a multi-stage compressor PP.

Like it the 1 until 9 indicate schematically, the at least one heat exchanger 20 can be viewed in the flow direction of the supply air L1 in the supply air line 11 after a single-flow or double-flow compressor P (see the 1 , 5 or 8th ) or after the first stage of a multi-stage compressor PP (see the 3 or 9 ) or after the second stage of the multi-stage compressor PP (see the 2 or 6 ) or both and ie after the first and after the second stage of a two-stage compressor PP (see the 4 and 7 ) be arranged.

Like it the 4 and 7 show, the at least one heat exchanger 20 can have a first heat exchanger 21 and a second heat exchanger 22. It is conceivable that the first heat exchanger 21 can be arranged after the first stage of the multi-stage compressor PP and the second heat exchanger 22 can be arranged after the second stage of the multi-stage compressor PP, viewed in the flow direction of the supply air L1 in the supply air line 11 . It is also conceivable that, viewed in the direction of flow of the exhaust air L2 in the exhaust air line 12, the first heat exchanger 21 can be arranged before or after the second heat exchanger 22 (see the dashed arrows in FIGS 4 and 7 ).

In the 1 until 9 one or two gas-coolant heat exchangers 31, 32 are also shown schematically in each case, which can optionally be provided in order to support the at least one passive heat exchanger 20 if required.

The above description of the figures describes the present invention exclusively within the framework of examples. It goes without saying that individual features of the embodiments can be freely combined with one another, insofar as this makes technical sense, without departing from the scope of the invention.

Claims (13)

Fuel cell system (100) comprising: at least one fuel cell (101) and a cathode system (10) for providing an oxygen-containing reactant in the form of supply air (L1) to the at least one fuel cell (101), wherein the cathode system (10) a supply air line (11) for providing the supply air (L1) to the at least one fuel cell (101) and an exhaust line (12) for discharging an exhaust air (L2) from the at least one fuel cell (101) having, wherein the cathode system (10) is designed to be recuperation-free, and wherein at least one heat exchanger (20) is provided between the supply air line (11) and the exhaust air line (12) of the cathode system (10), which is designed to passively transfer thermal energy from the supply air (L1) to the exhaust air (L2). . Fuel cell system (100) after claim 1 , characterized in that the at least one heat exchanger (20) is designed to be drive-free in order to passively transfer thermal energy from the supply air (L1) to the exhaust air (L2) without an electrical energy supply. Fuel cell system (100) after claim 1 or 2 , characterized in that the at least one heat exchanger (20) is designed to transfer thermal energy from the supply air (L1) to the exhaust air (L2) indirectly, in particular without mass transfer, e.g. by evaporation and condensation of a working medium, - in particular that the at least one heat exchanger (20) has a first chamber and a second chamber which are hermetically sealed and through which the supply air (L1) and the exhaust air (L2) are respectively conducted, with preferably the at least one heat exchanger (20) at least has a heat pipe or heat pipes, in which or in which a working medium medium is enclosed, - or that the at least one heat exchanger (20) has at least one first pipe and at least one second pipe, which are routed through the at least one heat exchanger (20) and through which the supply air and the exhaust air are respectively routed, wherein preferably the at least one heat exchanger (20) has a closed housing (21) in which a working medium is enclosed. Fuel cell system (100) according to one of the preceding claims, characterized in that the at least one heat exchanger (20) is designed to transfer thermal energy from the supply air (L1) to the exhaust air (L2) indirectly, in particular without mass transfer, in particular the at least one heat exchanger (20) is designed in the form of a gas-gas heat exchanger. Fuel cell system (100) according to one of the preceding claims, characterized in that a pressure control valve (Cvexh) is provided in the exhaust air line (12). Fuel cell system (100) according to the preceding claim, characterized in that the at least one heat exchanger (20) is arranged upstream of the pressure control valve (Cvexh) in the flow direction of the exhaust air in the exhaust air line (12). Fuel cell system (100) after claim 5 , characterized in that the at least one heat exchanger (20), seen in the flow direction of the exhaust air in the exhaust air line (12), is arranged after the pressure control valve (Cvexh), in particular that the pressure control valve (Cvexh) is designed as a three-way valve, or that the Pressure control valve (Cvexh) is designed as a pressure control valve (Cvexh+SV2) with an additional sealing function. Fuel cell system (100) according to one of the preceding claims, characterized in that in the supply air line (11) at least one compressor (P) is arranged, in particular the at least one compressor (P) as a single-flow compressor (P1), as a multi-flow compressor ( PP) or as a multi-stage compressor (PP). Fuel cell system (100) according to one of the preceding claims, characterized in that the at least one heat exchanger (20) viewed in the direction of flow of the supply air in the supply air line (11) after a single-flow or a multi-flow compressor (P, PP) or after the first stage a multi-stage compressor (PP) or after the second stage of the multi-stage compressor (PP). Fuel cell system (100) according to one of the preceding claims, characterized in that the at least one heat exchanger (20) has a first heat exchanger (21) and a second heat exchanger (22), in particular in the direction of flow of the supply air (L1) in the supply air line ( 11) the first heat exchanger (21) is arranged after the first stage of the multi-stage compressor (PP) and the second heat exchanger (22) after the second stage of the multi-stage compressor (PP), preferably in the flow direction of the exhaust air (L2) in viewed from the exhaust air line (12), the first heat exchanger (21) is arranged before or after the second heat exchanger (22), with the first heat exchanger (21) and the second heat exchanger (22) preferably having a plurality of divided or common heat coupling points and/or heat coupling paths. Fuel cell system (100) according to one of the preceding claims, characterized in that the at least one heat exchanger (20) has at least one silencer (23) at an outlet for the exhaust air from the exhaust air line (12) into the at least one heat exchanger (20), wherein in particular the at least one heat exchanger (20) has a second silencer (24) at an inlet for the exhaust air from the at least one heat exchanger (20) into the exhaust air line (12), and/or that in the air supply line (11) at least one gas Coolant heat exchanger (31, 32) is arranged. Method for operating a fuel cell system (100), comprising: at least one fuel cell (101) and a cathode system (10) for providing an oxygen-containing reactant in the form of an inlet air (L1) to the at least one fuel cell (101), the cathode system (10) an air supply line (11) for providing the air supply (L1) to the at least one fuel cell (101) and an exhaust air line (12) for removing an exhaust air (L2) from the at least one fuel cell (101), the cathode system (10) being recuperation-free is carried out, and wherein between the air supply line (11) and the Exhaust line (12) of the cathode system (10) at least one heat exchanger (20) is provided, which serves to passively transfer thermal energy from the supply air (L1) to the exhaust air (L2). Method according to the preceding claim, characterized in that an exhaust air (L2) heated by the at least one heat exchanger (20) is used to ventilate fuel-carrying components (VI) of the fuel cell system (100) and/or to temper components (V2) of the fuel cell system ( 100) and/or a terminal device.

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