WO2020064210A1 - Fuel cell system and method for operating a fuel cell system - Google Patents

Abstract

The invention relates to a method for operating a fuel cell system (100), which has at least one fuel cell (106), which is integrated into a coolant circuit (102) comprising a cooler (104) and in which a first coolant pump (108), for circulating a coolant, is present, and with which a bypass line (110) is associated, into which a second coolant pump (112), connected parallel to the first coolant pump (108), is integrated, comprising the steps: - determining that the cooler (104) is required to provide increased cooling power, which is higher than a current cooling power of the cooler (104), and - increasing a volume flow of the coolant conveyed through the cooler (104) by increasing a speed of the second coolant pump (112) integrated in the bypass line (110). The invention furthermore relates to a fuel cell system (100).

Description

 Fuel cell system

 and method for operating a fuel cell system

DESCRIPTION:

The invention relates to a method for operating a fuel cell system which has at least one fuel cell which is integrated into a coolant circuit comprising a cooler, in which there is a first coolant pump for circulating a coolant, and to which a bypass line is assigned, in which a second coolant pump connected in parallel to the first coolant pump is integrated. The invention further relates to a fuel cell system.

Fuel cell systems are used to provide electrical energy in the context of an electrochemical reaction, with this electrochemical reaction generating heat in the fuel cell in addition to the generation of electrical energy and product water. The fuel cell works most efficiently in a certain temperature interval, so that the heat generated is dissipated by the cooler through the cooler.

When using the fuel cell system in a motor vehicle, the structural conditions are limited, so that the coolant pump of the cooling circuit is likewise subject to a limitation with regard to its dimensions and therefore is also limited in its output. US 2017/0346109 A1 therefore proposes to connect two coolant pumps in the cooling circuit in series, which are smaller in size than the use of a single coolant pump. US Pat. No. 7,368,196 B2 also describes a fuel cell system which has a heat store in order to to be able to quickly put the fuel cell or a plurality of fuel cells combined in a fuel cell stack into normal operation in frost start conditions. For this purpose, the heat accumulator is integrated in a bypass line of the cooling circuit, to which a second coolant pump is assigned, so that the temperature interval required for efficient operation of the fuel cell can be reached quickly.

Operating states can occur in a fuel cell system, in which the result is a low coolant volume flow or a high heat input into the coolant. This does not result in optimal conditions for the fuel cells in the fuel cell stack or for the cooler, in particular the main water cooler, of a motor vehicle. Such operating states can occur, for example, after driving uphill, driving in extreme heat, driving under full load and in various dynamic operating cases.

It is therefore the object of the present invention to provide a fuel cell system and a method for operating such a fuel cell system, which enable a more efficient and dynamic setting of the coolant temperature.

This object is achieved by a method having the features of claim 1 and by a fuel cell system having the features of claim 9. Advantageous refinements with expedient developments of the invention are specified in the dependent claims.

The process is characterized in particular by the following steps:

Determine that the cooler has to provide an increased cooling capacity which is higher than an instantaneous cooling capacity of the cooler, at which in particular the operation of the first coolant pump alone is not sufficient, and Increasing a volume flow of the coolant delivered by the cooler by increasing a rotational speed of the second coolant pump integrated in the bypass line.

Due to this integration of a further coolant pump, the volume flow through the cooler can be increased without the operating conditions of the fuel cell or the fuel cell stack being changed. This contributes to improved cooling in the fuel cell system.

In this context, it has therefore proven to be advantageous if, when the volume flow of the coolant conveyed by the cooler is increased by means of the volume flow of the coolant conveyed by the fuel cell, is essentially maintained in a state which was required at the time of detection of the cooler increased cooling capacity was present. This also allows the volume flow through the cooler to be increased without changing the operating conditions of the fuel cell or the fuel cell stack. It is therefore possible that a completely separate and possibly much lower temperature can be set at the front, newly created cooler circuit, which contributes to lowering the temperature of the coolant supplied to the fuel cell.

The cooler circuit can be implemented in particular in that the volume flow through the cooler is increased by a part of the coolant emerging downstream from the cooler being sucked into the bypass line by the second coolant pump and being fed back to the cooler past the fuel cell. Thus, the coolant conducted through the bypass line and drawn in by the second coolant pump is not heated by waste heat from the fuel cell, so that when the cooler flows through again, it has to absorb a smaller amount of heat. Overall, a significantly lower temperature can be achieved for the coolant. It has proven to be advantageous if a control unit is present which regulates a speed of the first coolant pump and / or the speed of the second coolant pump as a function of a maximum cooling capacity that can be provided by the cooler and as a function of a cooling capacity currently required by the cooler . In other words, an additional operation of the second coolant pump is determined depending on the currently possible cooling capacity (including increasing the volume flow) and the necessary cooling capacity.

In order to make this speed control even more efficient, it has proven useful if a coolant temperature downstream of the fuel cell is measured upstream of the cooler and upstream of the bypass line by means of a temperature sensor. It can thus be detected what temperature the coolant has at the outlet of the fuel cell stack or at the outlet of the fuel cell, without the result being influenced by a part of the coolant which leads past the fuel cell.

The sensor data of the temperature sensor, in particular the thermometer, can be used to determine when the cooler has to provide increased cooling capacity. The increased cooling capacity of the cooler is preferably required when the coolant temperature measured by the temperature sensor reaches or exceeds a limit temperature.

It also makes sense if the speed of the second coolant pump is reduced or the second coolant pump is stopped when a temperature difference between the outside temperature and the coolant temperature in the cooler falls below a limit temperature difference. This ensures that the cooler can also provide sufficient cooling capacity, which is typically operated as a recuperator with outside air flowing past the coolant lines of the cooler, possibly with the aid of a fan. If the coolant temperature is too close to the outside temperature, efficient cooling is no longer possible and is no longer desirable if the outside temperature is very low. In this case it has proven to be advantageous if the one with the bypass line and the one in it second coolant pump realized cooler circuit is weakened or made inactive.

If the fuel cell system is used in a motor vehicle, it has proven to be advantageous if the required increased cooling capacity of the cooler is determined predictively and / or in relation to the power model, in particular on the basis of data from an operating history of the fuel cell system or in particular on the basis of forecast data. Visible temperatures or traffic conditions. In addition, it is possible to use expected route data entered in a navigation system of the motor vehicle to infer an expected increased cooling capacity requirement, for example because a mountain journey or journeys under full loads are to be expected.

The fuel cell system, which is particularly suitable for carrying out the method described above, has at least one fuel cell which is integrated in a coolant circuit comprising a cooler, in which there is a first coolant pump for circulating a coolant, and to which a bypass line is assigned is integrated into which a second coolant pump connected in parallel to the first coolant pump. This fuel cell system is characterized in that the coolant circuit has a branch to the bypass line upstream of the fuel cell, upstream of the first coolant pump and upstream of the second coolant pump, and that there is an opening in the coolant circuit into the coolant circuit downstream of the fuel cell.

This fuel cell system shows the advantage of improved cooling, the integration of the second coolant pump in a bypass can cause a significant increase in the volume flow conducted through the cooler, which has the effect similar to an enlarged coolant reservoir. In order to be able to provide a reliable setting option for achieving low temperatures at low loads, it has proven to be useful if a temperature sensor is provided upstream of the mouth for measuring the coolant temperature emerging from the fuel cell.

Further advantages, features and details of the invention result from the claims, the following description of preferred embodiments and the drawings. Show:

1 is a highly schematic representation of a fuel cell system comprising a coolant circuit, and

2 shows a time-dependent representation of the volume flow conveyed by the cooler (Q104, top) and a time-dependent representation of the speed of the coolant present in the cooler (V104, bottom), one at the entrance at approx. 497 seconds the coolant temperature required by the fuel cell is reduced.

FIG. 1 shows the part of a fuel cell system 100 that is required to explain the invention, the fuel cell system 100 comprising a coolant circuit 102, in which a cooler 104 is integrated and which has a first coolant pump 108 for circulating a coolant. A fuel cell 106, in particular a plurality of fuel cells 106 combined to form a fuel cell stack, is also integrated in the coolant circuit 102.

Each of the fuel cells 106 comprises an anode, a cathode and a proton-conductive membrane that separates the anode from the cathode. The membrane is formed from an ionomer, preferably a sulfonated tetrafluoroethylene polymer (PTFE) or a polymer of perfluorinated sulfonic acid (PFSA). Alternatively, the membrane can be formed as a sulfonated hydrocarbon membrane. A catalyst can additionally be admixed to the anodes and / or the cathodes, the membrane preferably being on its first side and / or on its second side with a catalyst layer made of a noble metal or a mixture comprising noble metals such as platinum, palladium, ruthenium or the like are coated, which serve as reaction accelerators in the reaction of the respective fuel cell 106.

Fuel (for example hydrogen) can be supplied to the anode via an anode compartment; in a polymer electrolyte membrane fuel cell (PEM fuel cell), fuel or fuel molecules are split into protons and electrons at the anode. The PEM lets the protons through, but is impermeable to the electrons. For example, the reaction takes place at the anode: 2H2 -> 4H ⁺ + 4e ^_ (oxidation / electron donation). As the protons pass through the PEM to the cathode, the electrons are conducted to the cathode or to an energy store via an external circuit. The cathode gas (for example oxygen or oxygen-containing air) can be supplied to the cathode via a cathode chamber, so that the following reaction takes place on the cathode side: O2 + 4H ⁺ + 4e ^_ -> 2H2O (reduction / electron absorption).

In order to ensure the ionic conductivity for hydrogen protons by the PEM, the presence of water molecules in the PEM is necessary. Therefore, the cathode gas in particular is humidified before it is fed to the fuel cell in order to bring about a moisture saturation of the PEM.

Since a plurality of fuel cells 106 are combined in the fuel cell stack, a sufficiently large amount of cathode gas must be made available, so that a large cathode gas mass flow is provided by a compressor, the temperature of which greatly increases as a result of the compression of the cathode gas . The conditioning of the cathode gas, i.e. its setting with regard to the desired parameters, takes place in a charge air cooler and in a humidifier.

A single fuel cell 106 is shown in FIG. 1 purely by way of example, to which reactants are supplied so that the electrochemical reaction for generating electrical energy can take place in a controlled manner in the fuel cell 106. A coolant circuit 102 with a cooler 104 is assigned to the fuel cell 106 to regulate the temperature of the fuel cell 106, and in particular to dissipate the heat generated during the electrochemical reaction, so that the cooler 104 can ensure that the coolant temperature at the inlet of the fuel cell 106 has the desired value. The coolant is heated as it passes through the fuel cell 106 or the fuel cell stack, so that the temperature of the coolant increases. In the present case, the coolant circuit 102 is assigned a bypass line 110, in which a second coolant pump 112 connected in parallel with the first coolant pump 108 is integrated. For this purpose, the coolant circuit 102 has a branch 118 to the bypass line 110 upstream of the fuel cell 106, upstream of the first coolant pump 108 and upstream of the second coolant pump 112, an opening 120 being provided in the coolant circuit 102, through which the bypass line 110 enters the coolant circuit 102 opens downstream of the fuel cell 106.

This configuration creates an additional cooler circuit 116 for the circulation of coolant, which can be controlled or actuated as required, which is formed from the bypass line 110 with the second coolant pump 112 integrated therein and the part of the coolant circuit 102 in which the cooler is located 104 is involved. In other words, the part of the coolant conveyed by the cooler circuit 116 is guided past the fuel cell 106, so that this part of the coolant does not pass through the fuel cell 106 and therefore does not absorb any heat. By integrating the second coolant pump 112, the volume flow through the cooler 104 can be increased without the operating conditions of the fuel cell 106 being significantly impaired or changed. If, for example, it turns out that the operation of the first coolant pump 108 in the cooling circuit 102 is insufficient in terms of performance in order to achieve the desired target temperature of the coolant, that is to say if the cooler 104 has to provide an increased cooling capacity which is higher than that of a momentary cooling capacity of the cooler 104 is increased, the volume flow of the coolant conveyed by the cooler 104 is increased by increasing the speed of the second coolant pump 112 integrated in the bypass line 110. There is preferably a control unit (not shown in any more detail) that pumps a speed of the first coolant pump 108 and / or the speed of the second coolant pump 112 as a function of a maximum cooling capacity that can be provided by the cooler 104 and as a function of a cooling capacity that is currently required by the cooler 104 regulates. When the volume flow of the coolant conveyed by the cooler 104 is increased, the volume flow of the coolant conveyed by the fuel cell 106 is preferably essentially maintained in a state which existed at the time of determining the increased cooling capacity required by the cooler 104.

It should be pointed out that one or more actuators and / or valves can be integrated in the bypass line 110, so that the bypass line 110 can be decoupled from the coolant circuit 102 by a corresponding configuration of the actuators and / or valves, which is achieved by the dashed line is indicated. In order to be able to record reliable information about the coolant temperature at the outlet of the fuel cell 106, that is to say downstream of the fuel cell 106, it has proven advantageous if downstream of the fuel cell 106 but upstream of the cooler 104, upstream of the bypass line 110 and upstream Line 122 a temperature sensor 114, in particular a thermometer is present. At the branch to line 122 there is preferably also a thermostatic valve 124 which is designed to supply the coolant via line 122 upstream of the first coolant pump 108 and downstream of the mouth 118 lead so that the coolant is then not cooled by the cooler 104 when the thermostatic valve 124 is in a suitable valve position, which may be necessary in certain operating modes of the fuel cell 106. FIG. 2 shows the volume flow Q104 conveyed by the cooler 104 and the speed of the coolant V104 flowing through the cooler 104, each in arbitrary units (au). Both the volume flow and the speed of the coolant increase significantly at about 497 seconds, since a lower temperature at the inlet of the fuel cell 106 is required here. At this time, the speed of the second coolant pump 112 is increased in such a way that the subsequently increased coolant flow and the subsequently increased speed of the coolant result. The second coolant pump 112 can initially be set from zero speed to an increased speed or from a predetermined speed to an even higher speed.

The fuel cell system 100 is characterized by improved cooling, the integration of the second coolant pump 112 in the bypass line 110 forming a smaller cooler circuit 116, which creates an additional setting option for reaching low temperatures with a low load on the fuel cell 106. This system is therefore subject to increased dynamics and has an effect similar to that of an enlarged coolant store.

REFERENCE SIGN LIST:

100 fuel cell system

 102 coolant circuit

 104 cooler (main water cooler)

 106 fuel cell

 108 first coolant pump

 110 bypass line

 1 12 second coolant pump

 1 14 temperature sensor

 1 16 radiator circuit

 1 18 junction

 120 mouth

 122 management

 124 thermostatic valve

Claims

EXPECTATIONS:

Method for operating a fuel cell system (100) which has at least one fuel cell (106) which is integrated in a coolant circuit (102) comprising a cooler (104) and in which a first coolant pump (108) for the circulation of a coolant is present and to which a bypass line (110) is assigned, into which a second coolant pump (112) connected in parallel with the first coolant pump (108) is integrated, comprising the steps:

 Determine that the cooler (104) has to provide an increased cooling capacity which is higher than a current cooling capacity of the cooler (104), and

 Increasing a volume flow of the coolant conveyed by the cooler (104) by increasing a rotational speed of the second coolant pump (112) integrated in the bypass line (110).

Method according to Claim 1, characterized in that when the volume flow of the coolant (104) conveyed by means of the cooler is increased by means of the volume flow of the coolant conveyed by the fuel cell (106) is essentially maintained in a state which at the time of Determining the increased cooling capacity required by the cooler (104) was present.

A method according to claim 1 or 2, characterized in that the volume flow through the cooler (104) is increased by a part of the coolant emerging downstream from the cooler (104) being sucked into the bypass line (110) by the second coolant pump (112) and past the fuel cell (106) to the cooler (104) again.

Method according to one of claims 1 to 3, characterized in that a control unit is provided which provides a speed of the first coolant pump (108) and / or the speed of the second coolant pump (112) depending on one of the cooler (104) Maximum cooling capacity and depending on a cooling capacity required by the cooler (104) that is currently required.

Method according to one of claims 1 to 4, characterized in that a coolant temperature downstream of the fuel cell (106) upstream of the cooler (104) and upstream of the bypass line (110) is measured by means of a temperature sensor (114).

A method according to claim 5, characterized in that the increased cooling capacity of the cooler (104) is required when the coolant temperature measured by the temperature sensor (114) reaches or exceeds a limit temperature.

Method according to one of claims 1 to 6, characterized in that the speed of the second coolant pump (112) is reduced or the second coolant pump (112) is stopped when a temperature difference between the outside temperature and the coolant temperature in the cooler (104) falls below a limit temperature difference .

Method according to one of Claims 1 to 7, characterized in that the required increased cooling capacity of the cooler (104) is determined predictively and / or based on the power model.

Fuel cell system (100) with at least one fuel cell (106) which is integrated in a coolant circuit (102) comprising a cooler (104), in which there is a first coolant pump (108) for circulating a coolant, and which has a bypass line (110 ) in which a second coolant pump (112) connected in parallel to the first coolant pump (108) is integrated, characterized in that

the coolant circuit (102) has a branch (118) to the bypass line (110) upstream of the fuel cell (106), upstream of the first coolant pump (108) and upstream of the second coolant pump (112), and that in the coolant circuit (102) a mouth (120) of the Bypass line (110) in the coolant circuit (102) downstream of the fuel cell (106) is present.

10. The fuel cell system (100) according to claim 9, characterized in that a temperature sensor (114) for measuring the coolant temperature emerging from the fuel cell (106) is present upstream of the mouth (120).