A fuel cell is a device for the direct conversion of chemical energy into electrical energy which—unlike a battery—has to be continuously supplied with energy carriers in the form of fuel and oxidizing agent. The fuel for conventional low-temperature fuel cells is hydrogen, although other high-temperature fuel cells which convert carbon monoxide, methane or natural gas at a working temperature of approx. 1000° C. are also known.
Fuel cells used for stationary applications can be used in combination with pressurized stores for fuel and oxidizing agent which can supply gas streams which can be varied very quickly depending on the desired electrical output power of the fuel cell.
It is not suitable to use pressurized stores for fuel cells in mobile use, for example as an energy source for electric vehicles, on the one hand on account of their high mass which has to be moved with the vehicles and on the other hand on account of the potential danger presented by a pressurized store filled with fuel, in particular hydrogen, in the event of the vehicle having an accident.
Therefore, systems which use what is known as a reformer, which converts an energy carrier which cannot be directly exploited by the fuel cell but can be successfully transported for this purpose, e.g. gasoline, into a useable energy carrier, in practice a gas mixture substantially comprising H2, CO2 and steam, are preferred for the mobile use of fuel cells. One drawback of the reformers compared to pressurized stores is that the flow of fuel which they deliver can only be varied slowly, typically with a time constant of the order of magnitude of 100 s, whereas the volumetric flow from a pressurized store can be regulated with a time constant of no more than 0.01 S.
Since, in operation, the fuel cell always contains a certain quantity of fuel, it is for a brief time possible to extract more electric power than the amount which corresponds to the quantity of fuel supplied, but this leads to undesirable shifts in the chemical conditions in the fuel cell. In conventional fuel cell systems, this can only be avoided by setting the flow of fuel provided by the reformer to be greater than the current which is normally collected from the fuel cell, so that a fuel reserve is available in the event of a sudden increase in demand for electric power. However, since this additional fuel cannot be stored for subsequent use in mobile systems, the excess fuel is generally not utilized efficiently, which is undesirable from a ecological and economic point of view.
It is an object of the present invention to provide a fuel cell system which, when the fuel supplied is used efficiently, allows rapid changes in the electrical output power of the system even if the flow of fuel supplied can only be changed slowly.
The object is achieved by a fuel cell system having the features of claim 1.
A system of this type allows a fuel cell to be operated with an electrical output power below a rated power of the cell for continuous operation by the fuel cell being operated intermittently in order to supply an electrical consumer with a low power, and in an operating phase in which the switch is closed, the fuel cell both supplies the consumer and charges the intermediate accumulator, whereas in an operating phase in which the switch is opened, the intermediate accumulator is responsible for supplying the electrical consumer.
Since the switch has to be able to switch under load, a semiconductor switch, in particular a MOSFET, is preferred.
The waste heat generated by a switch of this type can be used to good effect to heat the fuel cell if the latter is thermally coupled to the switch. In particular in the case of a fuel cell system having a stack of fuel cells, the switch is preferably arranged at one end of the stack, in order in this way to keep cells warm at the end of the stack, the temperature of which would otherwise drop undesirably compared to middle cells. Since the power loss which occurs at the switch in operation is greater than the heating power required to hold the stack at a desired operating temperature, a dedicated heating device for the fuel cell stack can be dispensed with.
The control circuit can control the opening and closing of the switch in each case on the basis of recorded values for a single operating parameter, or it can use one operating parameter to control the opening and a second operating parameter, which may be recorded by a different sensor, to control the closing.
The control circuit may be designed to continuously monitor the operating parameter(s) and to open the switch in each instance in response a first limit value being exceeded and to close the switch in response to a second limit value being intersected (by the same or a different operating parameter as in the case of the first limit value). Such a control strategy makes it possible for the available power to be precisely controlled to the power consumption of a consumer. In this case, the duration of an opening and closing cycle may be on the order of magnitude of a few seconds or more; the capacity of the intermediate accumulator must be dimensioned accordingly.
Another option is to include a pulse generator circuit in the control circuit which drives the switch with pulses whose pulse duty factor is variable as a function of the at least one operating parameter. This renders possible substantially shorter cycle times and/or operation of the switch with frequencies of up to 50 kHz. In this approach the required capacity of the intermediate accumulator is substantially lower, and voltage fluctuations at the consumer which result from the intermittent operation of the fuel cell, may be kept substantially smaller.
Suitable operating parameters to be monitored are in particular the terminal voltage of the fuel cell or, in the case of a stack of series-connected fuel cells, the terminal voltage or in particular the minimum cell voltage of all the cells of the overall stack, the internal resistance of an individual fuel cell or of a stack of fuel cells, or the hydrogen partial pressure of the cells. In this context, two different limit values for the same parameter can respectively be used as limit values for the opening and closing of the switch, or alternatively it is possible to use two limit values relating to different parameters. In particular if a cell voltage is used as criterion for opening of the switch, this voltage can be selected at such a low level that it allows CO oxidation in the cell(s). In particular if fuel cells are operated with reformer gas which may contain a CO content, this constituent, since it is not reacted under normal operating conditions, accumulates in the cells and leads to “poisoning” which manifests itself in an increase in the internal resistance of the cells and a drop in their terminal voltage, it being possible for the level of poisoning to differ for the individual cells of a stack.
The control circuit can also be used to control, in correlation with the control of the switch, the supply of fuel to the fuel cell or to a reformer which supplies the cell.
Further features and refinements of the invention will emerge from the following description of exemplary embodiments with reference to the appended figures, in which:
The fuel cell system shown in
A sensor 10 for recording an operating parameter of the fuel cell stack is connected to a control circuit 11. The sensor 10 may be a measuring circuit for recording an output voltage or an internal resistance of the fuel cell stack 4; it is also possible to provide a plurality of measuring circuits of this type in order for the output voltage and internal resistance in each case to be recorded separately for the individual cells of the stack 4. Chemical sensors, in particular for recording a hydrogen partial pressure in the cells of the stack, may also be considered. The monitoring of one or more of these parameters—it is also possible to provide a plurality of sensors in combination—allows the control circuit 11 to assess the power performance of fuel cell stack 4, more specifically the ratio between fuel supply and electrical power tapped off by the consumer 9.
First of all, by way of example, consideration will be given to the situation in which there are sensors 10 for in each case measuring terminal voltages of individual cells of the stack 4. When the switch 6 is closed and the fuel cells are load-free, as in the time interval t0 to t1 in
In principle, with the structure shown in
An option which is even more technically beneficial than that of regulating the electrical power of the fuel cell system by means of the supply of fuel is that of, conversely, allowing the control circuit 11 to regulate the fuel feed rate at the regulating valve 2 on the basis of the power required by the consumer 9. Brief fluctuations in the power demand of the consumer 9, as may occur in particular in mobile applications, can initially be absorbed by the intermediate accumulator 7. If an increased power demand is imposed for longer than what corresponds to the storage capacity of the intermediate accumulator 7, the fuel supply has to be readjusted. The control circuit 11 is able to estimate the power demand on the basis of the switching times t1, t2, t3, etc. The higher the power demand, the shorter the period of time [t1, t2] from closing of the switch until the voltage Umin reaches the lower limit value Ulow. By contrast, the duration of the subsequent recovery phase [t2, t3] is substantially dependent on the fuel feed rate. Therefore, the control circuit 11 keeps the ratio between these two time periods constant by, when it establishes that the time interval [t1, t2] has become shorter, actuating the control valve 2 in order to increase its throughput and, conversely, reducing its throughput when the period of time [t1, t2] becomes too long.
As has already been mentioned above, a CO content in the gas mixture delivered by the reformer can lead to poisoning of the cells of the stack 4, with the result that the internal resistance thereof increases, and their power delivery decreases. Carbon monoxide which has accumulated in a fuel cell in this way can be broken down by a temporary high electrical load forcing its output voltage below a limit value beyond which combustion of the CO commences in the cell. The lower voltage limit value Ulow can be selected to be below this limit value, so that in a load phase, in each case shortly before the switch 6 closes in the cell which supplies the voltage Umin and which will generally be the cell which is most strongly poisoned with CO, CO is broken down. If this breakdown phase is long enough to substantially completely breakdown the carbon monoxide in the cell, the performance of the cell is restored in the subsequent cycle, so that a different cell of the stack then delivers the lowest output voltage Umin. If the duration of the breakdown phase in insufficient to completely breakdown the CO, it nevertheless prevents a further drop in the performance of the cell and allows the stack 4 to continue to operate until the quantity of CO which has collected in all its cells is such that it is necessary to regenerate the entire stack.
If the CO poisoning is of only minor importance, operation below low cell voltages which allow the CO to be broken down in is not necessary or is only necessary from time to time. In this case, it may be desirable to increase the switching frequency of the switch 6 in order to reduce fluctuations in the voltage at the load connection terminals 8 and/or to reduce the quantity of energy which is to be stored in the intermediate accumulator 7 and thereby to allow a smaller, more lightweight and less expensive intermediate accumulator to be used.
A fuel cell system in accordance with a second configuration of the invention which satisfies these requirements is shown in
Since in the configuration shown in
In this configuration too, the microcontroller 12 expediently also controls the fuel throughput through a regulating valve 2, which controls either the direct flow of hydrogen to the fuel cell stack 4 or the flow of fuel to a reformer connected upstream of the stack 4.
In both configurations, the switch 6 is in each case arranged at an end side of the fuel cell stack 4, in order for its waste heat to additionally heat the end-side fuel cells, which otherwise, when using heating of equal power for all the fuel cells, would be lower than that of the cells located in the middle of the stack. In this way, the switch 6 is held at a temperature in the range from 70 to 95° C., which standard semiconductors are well able to withstand. Since its waste heat is used to control the temperature of the fuel cells, the deterioration in the overall efficiency of the system according to the invention only amounts to the extent to which the power loss of the switch 6 exceeds the heating power which is in any case required to control the temperature of the fuel cells.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/DE03/02844 | 8/26/2003 | WO | 9/1/2005 |