JP4155027B2 - Fuel cell system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell system that supplies hydrogen and air to a fuel cell body to generate power, and in particular, a hydrogen circulation type fuel cell system that circulates unused hydrogen in the fuel cell body to the inlet side of the fuel cell body. About.
[0002]
[Prior art]
In the fuel cell system, hydrogen gas and air are supplied to the hydrogen electrode and the air electrode of the fuel cell main body, respectively, and hydrogen and oxygen are reacted electrochemically in the fuel cell main body to obtain generated power. Such a fuel cell system is highly expected to be put into practical use, for example, as a power source for automobiles. Currently, research and development for practical use is actively performed.
[0003]
As a fuel cell main body used in a fuel cell system, a solid polymer type fuel cell main body is known as one particularly suitable for mounting in an automobile. In this solid polymer type fuel cell body, a membrane solid polymer is provided between a hydrogen electrode and an air electrode, and this solid polymer membrane functions as a hydrogen ion conductor. ing. In this solid polymer type fuel cell body, a reaction occurs in which hydrogen gas is separated into hydrogen ions and electrons at the hydrogen electrode, and water is generated from oxygen gas, hydrogen ions, and electrons at the air electrode. . At this time, the solid polymer film functions as an ionic conductor, and hydrogen ions move through the solid polymer film toward the air electrode.
[0004]
By the way, in order for the solid polymer film to function as an ion conductor, it is necessary to include a certain amount of moisture in the solid polymer film. For this reason, in a fuel cell system using such a solid polymer type fuel cell main body, the solid polymer membrane of the fuel cell main body is supplied by supplying hydrogen gas to the fuel cell main body while being humidified by a humidifier. It is generally performed to humidify.
[0005]
Further, as an effective method for humidifying the solid polymer membrane, a hydrogen circulation type fuel cell system is known in which unused hydrogen gas in the fuel cell body is circulated again to the fuel cell body for reuse. Yes. In this hydrogen circulation type fuel cell system, a little more hydrogen gas than the amount of hydrogen required for electric power consumed by a load connected to the outside of the fuel cell body (hereinafter referred to as an external load) is supplied to the hydrogen electrode of the fuel cell body. Then, unused hydrogen gas is discharged from the hydrogen electrode outlet, and this exhausted hydrogen (hereinafter referred to as circulating hydrogen) is returned to the hydrogen electrode inlet of the fuel cell main body for reuse. Since the circulating hydrogen discharged from the hydrogen electrode outlet contains a lot of water vapor, the circulating hydrogen containing a lot of water vapor is mixed with the dry hydrogen from the hydrogen tank and supplied to the hydrogen electrode of the fuel cell body. As a result, the solid polymer membrane of the fuel cell body is humidified.
[0006]
In the hydrogen circulation type fuel cell system described above, a slightly larger amount of hydrogen gas than the amount of hydrogen required for the electric power consumed by the external load is supplied to the hydrogen electrode of the fuel cell main body. Therefore, the flow rate of hydrogen supplied to the hydrogen electrode is larger than the amount of hydrogen necessary for power generation. At this time, if only the amount of hydrogen necessary for power generation is supplied to the hydrogen electrode, hydrogen will not efficiently reach the cells near the hydrogen electrode outlet and the power generation efficiency will be reduced. By supplying more hydrogen gas than the amount to the hydrogen electrode, power generation in all the cells of the fuel cell system can be performed with high efficiency. In the fuel cell system, the same can be said for the air electrode. Therefore, not only the amount of oxygen (air) necessary for power generation is supplied, but a little extra oxygen is supplied to the air electrode. The ratio of the amount of hydrogen (air) actually supplied to the amount of hydrogen (air) required for power generation is usually called the raw material stoichiometric ratio, but this raw material stoichiometric ratio is set to an optimum value of 1 or more for the above reason. Has been.
[0007]
However, even when the raw material stoichiometric ratio is set to an optimum value, more hydrogen and air are required when the external load increases rapidly. Such a change in the raw material increases because there is a time delay until it reaches the fuel cell electrode, and thus a shortage of the raw material occurs transiently in the fuel cell electrode, causing a decrease in the generated voltage. Even when a transient shortage of raw materials occurs in this way, the external load usually tries to take out constant power. Therefore, when the generated voltage decreases as described above, a large amount of load current is taken out to make the load constant. It becomes like this. When the load current increases, a voltage drop occurs due to the action of the internal resistance of the fuel cell main body, which causes a further voltage drop. Due to such a vicious cycle, the voltage lowers below the lower limit value, which may damage the fuel cell body. For this reason, when driving an external load with a fuel cell, it is necessary to consider the fuel cell voltage simultaneously with the load current, especially during a transient when the external load increases rapidly.
[0008]
As a method of operating the fuel cell during the transition, a method is known in which the load current extraction amount is limited so that the load current extracted from the fuel cell main body has a desired trajectory (see, for example, Patent Document 1). .
[0009]
[Patent Document 1]
Japanese Unexamined Patent Publication No. 7-57553
[0010]
[Problems to be solved by the invention]
However, even when only the load current is limited as in Patent Document 1, a shortage of the raw material may occur transiently due to a time delay of the increase in the raw material during a sudden change in the operating load, causing a decrease in the generated voltage. As described above, since the external load keeps taking out a constant load, the load current increases, which further causes a voltage drop. When such a voltage drop is significant, the voltage lowers below the lower limit value, which may damage the fuel cell body.
[0011]
By the way, in order to prevent the shortage of raw materials in the fuel cell, it is sufficient to take out the load slowly, but the response performance deteriorates. On the contrary, if the load is taken out rapidly in order to improve the response performance, the above-mentioned raw material shortage is caused. Since the characteristics of the battery change over time and change according to the operating state of the battery, it is necessary to achieve both a load take-out response corresponding to the operating state at that time and prevention of damage due to the voltage drop.
[0012]
Therefore, the present invention provides a fuel cell system that can prevent a voltage drop due to a shortage of raw materials and cause a voltage lower than a lower limit value when an external load increases, and can take out a load current with good response. For the purpose.
[0013]
[Means for Solving the Problems]
A fuel cell system according to the present invention includes a fuel cell main body, a hydrogen supply device that supplies hydrogen as a raw material gas to the fuel cell main body, an air supply device that supplies air as a raw material gas to the fuel cell main body, Necessary supply raw material flow rate calculation means for calculating a supply flow rate of the required raw material gas to the fuel cell main body based on a predetermined load current, and each raw material gas when the actual supply flow rate increases to the required supply flow rate Raw material supply response characteristic setting means for setting a target response characteristic based on the response characteristic; target load extraction trajectory setting means for setting a trajectory for extracting the predetermined load current from the fuel cell main body based on the target response characteristic; Load current change prediction calculating means for calculating a change in the future load current based on the trajectory for taking out the predetermined load current, the change in the future load current and the fuel cell book And a target load for correcting the trajectory set by the target load take-out trajectory setting means based on the magnitude of the voltage change. And a take-out trajectory correcting means. The predetermined load current is extracted from the fuel cell main body in a new trajectory corrected by the target load extraction trajectory correcting means.
[0014]
In the fuel cell system according to the present invention described above, the target load trajectory is set and corrected based on the target response characteristics of the source gas, so that the source gas responds to the response of the source gas when it is increased to the required supply flow rate. The load current is taken out. Further, according to the present invention, the load current extraction trajectory set in advance is corrected based on the future voltage change predicted based on the state of the fuel cell main body, and the load extraction trajectory is the fuel cell at that time. It is possible to determine whether or not it is suitable for the operating state of the main body. If not, specifically, if the predicted voltage value of the fuel cell body is lower than the voltage lower limit value, a predetermined load current extraction trajectory set in advance is corrected.
[0015]
【The invention's effect】
According to the fuel cell system of the present invention, since the load current is taken out in accordance with the response of the raw material gas, the shortage of the raw material in the fuel cell main body can be prevented when the load changes transiently. Further, it is possible to prevent a voltage drop of the fuel cell main body due to the shortage of raw materials.
[0016]
Further, according to the fuel cell system, when the load changes in a transient manner, the load can be taken out with good response according to the operating state of the fuel cell main body at that time, and the voltage of the fuel cell main body is increased. It becomes possible to prevent the battery itself from being damaged below the lower limit value.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, specific embodiments of a fuel cell system according to the present invention will be described in detail with reference to the drawings.
[0018]
(First embodiment)
A first embodiment of the present invention will be described with reference to FIG. The fuel cell system 1 of the first embodiment includes a solid polymer type fuel cell main body 2 having a solid polymer film as an electrolyte. The fuel cell main body 2 generates electricity by electrochemically reacting oxygen in the air supplied to the air electrode as a raw material gas and hydrogen supplied to the hydrogen electrode.
[0019]
In the fuel cell main body 2, an air supply device 4 such as a compressor or a blower is connected to an air electrode inlet via an air supply pipe 3. The air whose flow rate and pressure are adjusted by the air supply device 4 is supplied to the air electrode inlet of the fuel cell main body 2 through the air supply pipe 3.
[0020]
In the fuel cell system 1, not all of the air supplied from the air electrode inlet is consumed, but oxygen remaining without being consumed and other components in the air are discharged from the exhaust air pipe 5 as exhaust air. . The exhaust air pipe 5 is open to the atmosphere, and the exhaust air is released into the atmosphere.
[0021]
In addition, the fuel cell main body 2 is connected to a hydrogen electrode inlet via a hydrogen supply pipe 6, for example, a hydrogen supply device 7 composed of a hydrogen tank or the like. A hydrogen supply valve 8 is arranged in the middle of the hydrogen supply pipe 6, and a target flow rate of hydrogen gas (hereinafter referred to as raw material hydrogen) is supplied from the hydrogen supply device 7 to the hydrogen electrode inlet side of the fuel cell body 2. It can be supplied.
[0022]
The fuel cell system 1 is configured as a hydrogen circulation type, and is a circulating hydrogen pipe that serves as a path for exhaust hydrogen (circulated hydrogen) discharged from the fuel cell main body 2 without being used for power generation in the fuel cell main body 2. 9 is provided. A hydrogen circulation pump 10 is disposed in the middle of the circulation hydrogen pipe 9, and circulating hydrogen containing a large amount of water vapor discharged from the fuel cell main body 2 is circulated by the hydrogen circulation pump 10. It is circulated to the hydrogen electrode inlet side of the fuel cell main body 2 through the pipe 9 for use and joins the raw material hydrogen supplied from the hydrogen supply device 7. Therefore, in the fuel cell system 1, the mixed hydrogen of the raw hydrogen supplied from the hydrogen supply device 7 and the circulating hydrogen containing a large amount of water vapor is supplied to the hydrogen electrode of the fuel cell main body 2. Thus, in the fuel cell system 1, the solid hydrogen film of the fuel cell main body 2 is humidified by mixing the circulating hydrogen rich in water vapor with the raw material hydrogen and supplying it to the hydrogen electrode of the fuel cell main body 2. ing. In addition, in order to further improve the humidification effect, a humidifier may be separately installed at the subsequent stage of the hydrogen supply device 7. By installing such a humidifier, the hydrogen electrode of the fuel cell main body 2 is supplied with the mixed hydrogen of the raw material hydrogen and the circulating hydrogen that are humidified by passing through the humidifier. The solid polymer film of the main body 2 can be sufficiently humidified.
[0023]
Further, in the fuel cell system 1, an exhaust hydrogen pipe 12 provided with a purge valve 11 for releasing surplus hydrogen gas and water vapor in the circulating hydrogen pipe 9 into the atmosphere is a circulating hydrogen pipe. 9 It is branched and provided.
[0024]
The fuel cell body 2 is connected to an external load 13 that consumes the power generated by the fuel cell body 2. Specifically, for example, an inverter is connected to the fuel cell main body 2 as the external load 13, and power generated by the fuel cell main body 2 is converted into energy by the inverter and supplied to a drive motor or the like. This drive motor is used as power for driving the vehicle when the fuel cell system 1 is applied to a vehicle. In the present embodiment, a power generation amount is set for the external load 13, and the load is taken out as a load current from the fuel cell main body 2 based on the power generation amount.
[0025]
A voltage sensor 14 and a load current sensor 15 are arranged between the fuel cell main body 2 and the external load 13, and the generated voltage in the fuel cell main body 2 is detected by the voltage sensor 14, and the load current sensor 15 A load current supplied from the fuel cell main body 2 to the external load 13 is detected.
[0026]
The fuel cell main body 2 is provided with a temperature sensor 16 that detects the operating temperature of the fuel cell main body 2. In the fuel cell system 1, heat is generated during the reaction in the fuel cell main body 2, but it is cooled by a cooling mechanism (not shown) and the operating temperature of the fuel cell main body 2 is monitored by the temperature sensor 16. Operation at an optimum temperature is possible.
[0027]
And the fuel cell system 1 is provided with the controller 17 used as the principal part of this invention. The controller 17 includes a CPU, a ROM, a RAM, a CPU peripheral circuit, and the like, and has a microprocessor configuration in which these are connected via a bus. In the controller 17, the CPU executes a control program stored in the ROM using the RAM as a work area, and as shown in FIG. A function as the characteristic setting means 19, a function as the target load take-out trajectory setting means 20, a function as the load current change prediction calculation means 21, a function as the voltage change prediction calculation means 22, and a target load take-out trajectory correction means 23 as a function is realized.
[0028]
The required feed flow rate calculation means 18 obtains the target load value in the fuel cell body 2 based on the current value (target load value) of the load current that is requested by the external load 13 and should be taken out to the external load 13. For this purpose, the supply flow rate of the raw material gas, specifically hydrogen or air, is calculated.
[0029]
Further, the raw material supply response characteristic setting means 19 shows the response characteristics when the actual supply flow rate is increased up to the supply flow rate of the raw material gas calculated by the necessary supply raw material flow rate calculation means 18 for each of hydrogen and air. The target response characteristics are further set from these. The target response characteristic is selected and set, for example, among the response characteristics set for the settings of hydrogen and air.
[0030]
The target load take-out trajectory setting means 20 sets a trajectory (target load trajectory) from which the external load 13 takes out the target load value based on the target response characteristic set by the raw material supply response characteristic setting means 19. It is.
[0031]
Further, the load current change prediction calculating means 21 calculates a future change in load current based on the target load trajectory set by the target load take-out trajectory setting means 20.
[0032]
Further, the voltage change prediction calculation means 22 is based on the change in the target load current calculated by the load current change prediction calculation means 21 and the state of the fuel cell main body 2 at that time. It predicts voltage changes.
[0033]
The target load take-out trajectory correcting means 23 corrects the target load trajectory set by the target load take-out trajectory setting means 20 based on the magnitude of the voltage change predicted by the voltage change prediction calculating means 22. To do.
[0034]
In the fuel cell system 1, a target load trajectory in which the external load 13 extracts the target load value is set based on the target response characteristic of the raw material gas by the processing in the controller 17. Then, from this target load trajectory, a change in load current and a change in the voltage of the fuel cell main body 2 are predicted, and if it is necessary to correct the target load trajectory based on this prediction, a new trajectory is corrected. The load current is taken out at. In the fuel cell system 1, the change in the voltage of the fuel cell body 2 is predicted according to the state of the fuel cell body 2, for example, the operating temperature detected by the temperature sensor 16.
[0035]
According to the fuel cell system 1 as described above, since the target load trajectory is set based on the target response characteristics of the raw material gas, the load is taken out in accordance with the response of the raw material when the raw material is increased to the required amount, that is, Supply of load current to the external load 13 is performed. Accordingly, it is possible to prevent a voltage drop due to a shortage of raw material in the fuel cell main body 2 when the load changes transiently.
[0036]
Further, according to the fuel cell system 1, since the load is taken out by the external load 13 from the future voltage change predicted based on the state of the fuel cell main body 2, the target load trajectory is the operation of the fuel cell main body 2 at that time. It becomes possible to judge whether or not the state is adapted. If not, specifically, if the predicted voltage value of the fuel cell main body 2 is lower than the lower voltage limit, the load extraction trajectory by the external load 13 is corrected and the new target load is corrected. The load is taken out on the track. Therefore, when the load changes transiently, the load can be taken out with good response according to the operating state of the fuel cell main body 2 at that time, and the voltage of the fuel cell main body 2 becomes lower than the lower limit value. Damage to the battery itself can be prevented.
[0037]
(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. The basic configuration of the fuel cell system of the second embodiment is the same as that of the fuel cell system 1 of the first embodiment, but the processing content in the controller 30 is the same as that of the fuel cell system 1 of the first embodiment. Is different. Hereinafter, the processing content of the controller 30 which is a characteristic point of the fuel cell system of the second embodiment will be described. In addition, the same code | symbol is attached | subjected about the structure similar to the said 1st Embodiment, and detailed description is abbreviate | omitted.
[0038]
The controller 30 included in the fuel cell system according to the second embodiment has the same microprocessor configuration as the controller 17 included in the fuel cell system 1. In the controller 30, the CPU executes the control program stored in the ROM using the RAM as a work area, and as shown in FIG. , Function as raw material supply response characteristic setting means 19, function as target load extraction trajectory setting means 20, function as load current change prediction calculation means 21, function as voltage change prediction calculation means 22 And the function as the target load take-out trajectory correcting means 23 are realized. In addition to these functions, the function as the voltage correction amount calculating means 31 and the function as the load current correction amount calculating means 32 are provided. Functions are realized.
[0039]
The voltage correction amount calculation means 31 determines that the voltage of the fuel cell body 2 is equal to or higher than the lower limit value when the voltage change of the fuel cell body 2 predicted by the voltage change prediction means 22 may fall below a predetermined voltage lower limit value. Thus, the voltage correction amount is calculated.
[0040]
The load current correction amount calculation means 32 calculates a load current correction amount based on the voltage correction amount calculated by the voltage correction amount calculation means 31 and the state of the fuel cell main body 2 at that time.
[0041]
In this controller 30, the target load take-out trajectory correcting means 23 is set to the target load take-out trajectory setting means 20 based on the load current correction amount calculated by the load current correction amount calculating means 32. Correct the load trajectory.
[0042]
In the fuel cell system having the controller 30 as described above, when the voltage change in the fuel cell main body 2 is lower than a predetermined voltage lower limit value due to processing in the controller 30, the voltage and load current exceed the lower limit value. A correction amount is calculated. Then, the target load trajectory is corrected based on the calculated load current correction amount, and the load is taken out using the new target load trajectory. Further, in the fuel system of the present embodiment, the calculation of the correction amount of the load current is performed based on the state of the fuel cell main body 2.
[0043]
According to the fuel cell system of the second embodiment as described above, when the load transiently increases and changes, the predicted value of the voltage change in the fuel cell main body 2 is less than the voltage lower limit value. However, since the load take-out trajectory is corrected based on the state of the fuel cell main body 2 so that it always exceeds the lower limit value, the fuel cell main body 2 will run out of raw materials and damage the battery itself due to a voltage drop. Can be prevented. In addition, when the load changes transiently, the fuel cell voltage can be prevented from dropping transiently, and the load response is not delayed more than necessary by minimizing the correction of the load take-out trajectory. Can be.
[0044]
(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. The basic configuration of the fuel cell system of the third embodiment is the same as that of the fuel cell system 1 of the first and second embodiments, but the processing content in the controller 40 is the first and second embodiments. Is different. Hereinafter, the processing content of the controller 40 which is a characteristic point of the fuel cell system of the third embodiment will be described. In addition, the same code | symbol is attached | subjected about the structure similar to the said 1st and 2nd embodiment, and detailed description is abbreviate | omitted.
[0045]
The controller 40 included in the fuel cell system according to the third embodiment has the same microprocessor configuration as the controller 17 included in the fuel cell system 1. In the controller 40, the CPU functions as the required feed flow rate calculation means 18 as shown in the figure by executing a control program stored in the ROM using the RAM as a work area as shown in FIG. A function as the raw material supply response characteristic setting means 19, a function as the target load take-out trajectory setting means 20, a function as the load current change prediction calculation means 21, a function as the voltage change prediction calculation means 22, and a target A function as the load take-out trajectory correcting means 23, a function as the voltage correction amount calculating means 31, and a function as the load current correction amount calculating means 32 are realized. In addition to these functions, hydrogen supply A function as the amount correction means 41, a function as the hydrogen supply response characteristic correction means 42, and a function as the air supply amount correction means 43; And functions as an air supply response characteristics correcting means 44, and the function as a starting material response characteristic modifying means 45 is adapted to be realized.
[0046]
The hydrogen supply amount correction means 41 is a load current whose change is predicted by the load current change prediction means 21 before being corrected by the calculation result of the load current correction amount calculation means 32, an actual load current, specifically Is to correct the flow rate of hydrogen supplied to the fuel cell body 2 so that the load current detected by the load current sensor 15 matches. As the correction operations executed to correct the hydrogen flow rate in the hydrogen supply amount correction means 41 in this way, the opening operation of the purge valve 11, the rotation speed operation of the hydrogen circulation pump 10, and the opening operation of the hydrogen supply valve 8 are performed. Yes, the hydrogen supply amount correction means 41 selects one or more of these operations, and calculates the operation amount of the selected purge valve 11, hydrogen circulation pump 10 or hydrogen supply valve 8.
[0047]
The hydrogen supply response characteristic correcting means 42 corrects the hydrogen response characteristic set by the raw material supply response characteristic setting means 19 based on the correction operation selected by the hydrogen supply amount correction means 41. It is.
[0048]
In addition, the air supply amount correction unit 43 calculates the load current that is predicted to change in the load current change prediction unit 21 and the actual load current before being corrected based on the calculation result of the load current correction amount calculation unit 32. The flow rate of air supplied to the fuel cell main body 2 is corrected so as to match. As the correction operation executed to correct the air flow rate in the air supply amount correction means 43 in this way, there are the rotation speed operation of the air supply device 4 and the opening operation of the air electrode pressure adjustment valve, and the air supply amount correction The means 43 selects one or more of these operations and calculates the operation amount of the selected air supply device 4 or air electrode pressure adjustment valve.
[0049]
The air supply response characteristic correcting means 44 corrects the air response characteristic set by the raw material supply response characteristic setting means 19 based on the correction operation selected by the air supply amount correction means 43. It is.
[0050]
The raw material response characteristic correcting means 45 is slower among the hydrogen response characteristic corrected by the hydrogen supply response characteristic correcting means 42 and the air response characteristic corrected by the air supply response characteristic correcting means 44. A response characteristic is selected, and the target response characteristic set by the raw material supply response characteristic setting means 18 is corrected to the selected response characteristic.
[0051]
In the fuel cell system having the controller 40 as described above, when the voltage change in the fuel cell main body 2 falls below a predetermined voltage lower limit value due to processing by the controller 40, not only the target load trajectory is corrected, but also the correction is made. A flow rate correcting operation for increasing the raw material flow rate is executed so as to achieve the raw material flow rate that realizes the previous target load trajectory, and the response characteristics of each raw material are corrected to the response characteristics after the flow rate increase. Then, the slower response characteristic among the response characteristics of these new raw materials is set as a new target response characteristic.
[0052]
Here, an example of the processing by the controller 40 as described above will be specifically described with reference to the flowchart of FIG.
[0053]
First, a flag (FLAG_A) for determining whether or not this operation flow has been executed even once is checked (step S1). When the value of the flag is 1, that is, when this operation flow is executed once or more, the process proceeds to Step S4 described later. When the value of the flag is 0, that is, when this operation flow has never been executed, the controller 40 functions as the raw material supply response characteristic setting means 19 to set the target response characteristic of the raw material gas. (Step S2). This target response characteristic is calculated based on the required raw material flow rate calculated from the target load value and the raw material stoichiometric ratio in the controller 40 functioning as the necessary supply raw material flow rate calculating means 18 in this embodiment.
[0054]
In the present embodiment, the response characteristics of each raw material are measured in advance by experiments, approximated by first-order lag characteristics and stored, and based on these, the target response characteristics are set in step S2. The necessary raw material flow rate is calculated using the following formula (1) or formula (2).
[0055]
Required hydrogen flow rate [L / min] = hydrogen flow rate required for reaction [L / min] × hydrogen stoichiometric ratio (1)
However, the hydrogen flow rate required for the reaction [L / min] = load current [A] × coefficient × number of cells. Here, the coefficient = 0.00696 = (1 / Faraday constant) /2×22.4 [L / mol] × 60, the number of cells = 270, and the Faraday constant = 9.6648456 × 104 [c / mol]. is there.
[0056]
Necessary air flow rate [L / min] = required air flow rate [L / min] × air stoichiometric ratio (2)
However, the air flow rate required for the reaction [L / min] = the oxygen flow rate required for the reaction [L / min] / the ratio of oxygen in the air, and the oxygen flow rate required for the reaction [L / min] = coefficient × load current. [A] × number of cells, ratio of oxygen in air = 0.21. Here, coefficient = 0.0348 = 0.0692 / 2, and the number of cells = 270.
[0057]
Here, of these hydrogen and air, the slower response characteristic is set as the target response characteristic, and which response is faster depends on the system configuration. Usually, the air supplied by an air supply device such as a compressor or a blower has a slower response, and even in this embodiment, the air has a slower response than hydrogen. Set as target response characteristics.
[0058]
Next, the controller 40 functions as the target load take-out trajectory setting means 20, and a load trajectory having a response characteristic that matches the target response characteristic set in step S2 is set as the target load trajectory (step S3). In this embodiment, since the target response characteristic is approximated by a first-order lag function, the target load trajectory is also set as a first-order lag function having the same time constant.
[0059]
Next, the controller 40 functions as the load current change prediction calculation means 21, and a future load current change (target load current) is predicted and calculated based on the target load trajectory set in step S3 ( Step S4). In the present embodiment, since the target load trajectory is a first order lag function, the target load current is a first order lag function that can be calculated in time series. Therefore, the target load current can be predicted and calculated by the load current change prediction calculating means 21 until a predetermined future time.
[0060]
Next, the controller 40 functions as the voltage change prediction calculation means 22 and the change in voltage in the fuel cell body 2 is predicted using the predicted value of the target load current predicted and calculated in step S4 (step S4). S5). In the present embodiment, the voltage change is predicted by referring to the current-voltage characteristics (IV characteristics) of the fuel cell system. As shown in FIG. 6, if a plurality of IV characteristics are prepared according to the operating temperature of the fuel cell main body 2, for example, the voltage according to the operating temperature of the fuel cell main body 2 detected by the temperature sensor 16. Can be predicted.
[0061]
Then, it is determined whether or not the voltage change may fall below a lower limit value (step S6). If the value does not fall below the lower limit, 0 is substituted into the identification variable FLAG_A (initialization) so that the process starts again from step S2 in the next control cycle (step S7), and thereafter each process is performed again. Is processed to be repeated. On the other hand, if the lower limit value is sometimes exceeded, the controller 40 functions as the voltage correction amount calculating means 31 to calculate the voltage correction amount that makes the voltage of the fuel cell body 2 equal to or higher than the lower limit value (step). S8).
[0062]
Next, the controller 40 functions as the load current correction amount calculation means 32, and the load current correction amount is calculated based on the voltage correction amount calculated in step S8 (step S9). In the present embodiment, the load current correction amount is calculated with reference to the IV characteristic (see FIG. 6) of the fuel cell system, similarly to the voltage change prediction in step S5.
[0063]
Thereafter, the controller 40 functions as the target load take-out trajectory correcting means 23, and the target load trajectory set in the step S3 is corrected based on the load current correction amount calculated in the step S9 (step S10). . In the present embodiment, as shown in FIG. 7, since the target load current trajectory and the target load trajectory have the same response characteristics, first, the target load current calculated in step S4 based on the load current correction amount is used. The target load trajectory is corrected such that the shape of the response characteristic of the trajectory of the target load current thus corrected is the response characteristic of the target load trajectory.
[0064]
Further, the controller 40 corrects the target response characteristic of the supply flow rate of the raw material gas set in step S2 along with the correction of the target load trajectory. First, the controller 40 functions as the hydrogen supply amount correction means 41, so that the target load current calculated before the load current correction amount calculated at step S9, that is, the target load current calculated at step S4, and the load current are calculated. A hydrogen flow rate correction operation that is executed to match the actual load current detected by the sensor 15 is selected, and an operation amount in the selection operation is calculated (step S11). In the present embodiment, the opening operation of the purge valve 11 is selected and executed among the opening operation of the purge valve 11, the rotation speed operation of the hydrogen circulation pump 10, and the opening operation of the hydrogen supply valve 8. Further, when the opening operation of the purge valve 11 is saturated, that is, even if the purge valve 11 is operated until the maximum opening is reached, the target load current calculated in step S4 and the actual load current do not coincide with each other. When the flow rate is insufficient, the rotation operation of the hydrogen circulation pump 10 is executed, and when the rotation operation of the hydrogen circulation pump 10 is saturated, the opening operation of the hydrogen supply valve 8 is executed. ing.
[0065]
In this embodiment, the emphasis is on compensating for the response slowed down by the correction of the load current (step S9), and the hydrogen supply response (varies depending on the system configuration) so that this response delay is efficiently eliminated. Therefore, the correction operations are selected and executed in order of speed, but the order is not limited to this order. For example, the power consumption is low with an emphasis on fuel efficiency. You may make it select in order.
[0066]
Next, the controller 40 functions as the hydrogen supply response characteristic correcting means 42, and the hydrogen response characteristic used in setting the target response characteristic is corrected based on the operation amount correction operation calculated in step S11. (Step S12). In the present embodiment, response characteristics are measured in advance from experiments and stored in the controller 40 for reference.
[0067]
The controller 40 corrects not only the hydrogen response characteristic but also the air response characteristic. In the controller 40, by functioning as the air supply amount correction means 43, an air flow rate correction operation that is executed to match the target load current calculated in step S4 with the actual load current is selected. The operation amount in the selection operation is calculated (step S13). In step S13, one or more operations are selected from among the rotation speed operation of the air supply device 4 and the opening operation of the air electrode pressure adjustment valve. However, in this embodiment, the air electrode pressure adjustment valve is not provided. The rotation speed operation of the air supply device 4 is executed. In the case where an air electrode pressure adjusting valve is provided and when emphasis is placed on compensating for the response slowed down by the correction of the load current (step S9), the opening of the air electrode pressure adjusting valve is firstly performed. The operation may be selected and executed, and when the opening operation of the air electrode pressure adjustment valve is saturated, the rotation speed operation of the air supply device 4 may be executed. You may make it do.
[0068]
Next, the controller 40 functions as the air supply response characteristic correction means 44, and the air response characteristic used in setting the target response characteristic is corrected based on the operation amount correction operation calculated in step S13. (Step S14). In the present embodiment, response characteristics are measured in advance from experiments and stored in the controller 40 for reference.
[0069]
Then, the controller 40 functions as the raw material response characteristic correcting means 45, and the hydrogen response characteristic corrected in the step 12 is compared with the air response characteristic corrected in the step S14, and the slower response characteristic is obtained. The target response characteristic is corrected by selecting and replacing the target response characteristic set in step S2 (step S15).
[0070]
Finally, 1 is assigned to the identification variable FLAG_A so that the process is started from step S4 in the next control cycle (step S16), and thereafter, the process is repeated again.
[0071]
According to the fuel cell system of the third embodiment as described above, the output of the load current change prediction calculation unit 21 and the actual detected by the load current sensor 15 before correction by the load current correction amount calculation unit 32 are performed. Since one or more correction operations are selected and executed to match the load current and the supply flow rate of the raw material gas is corrected, the fuel cell main body can be used even when the load changes transiently. The shortage of raw materials in 2 can be reduced.
[0072]
In addition, the target response trajectory is corrected along with the target load trajectory, so that a fast response according to the target load trajectory is realized before the correction, and the fuel cell when the load changes transiently The shortage of raw material in the main body 2 can be more effectively reduced, and the target response characteristic can be accelerated after correction for increasing the flow rate of the raw material gas. It is possible to prevent damage to itself and to prevent the load response from being delayed more than necessary.
[0073]
Further, when correcting a plurality of correction operations, specifically, the hydrogen flow rate, the opening operation of the purge valve 11, the rotation speed operation of the hydrogen circulation pump 10, the opening operation of the hydrogen supply valve 8, and the air flow rate are corrected. Since one or more of the rotation speed operation of the air supply device 4 and the opening operation of the air electrode pressure adjustment valve are selected and executed, even when one operating range reaches saturation, it continues. By executing other operations, it becomes possible to cope with a larger load change, and it is possible to expand the range of load changes that can be handled.
[0074]
Further, when each raw material flow rate is corrected to be increased by the hydrogen supply amount correction means 41 and the air supply amount correction means 43, for example, when the opening of the purge valve 11 is increased, the inlet side of the hydrogen electrode of the fuel cell body 2 The pressure difference between the outlet and the outlet increases, and the hydrogen supply response characteristic becomes faster. A similar effect can be seen when the number of revolutions of the hydrogen circulation pump 10 is increased or when a correction operation is performed so as to increase the air flow rate. In the present embodiment, even when a correction operation is performed such that the response characteristics of each source gas become faster, the hydrogen supply response characteristic correction means 42 and the air supply response characteristic correction means 44 as described above. Since the response characteristic of each raw material is corrected in consideration of the response change, the time delay until the increase change of the raw material gas reaches the fuel cell main body 2 can be corrected. In the present embodiment, since the target load trajectory for load extraction is set based on the target response characteristic, the load response is delayed more than necessary by correcting the response characteristic of each raw material gas as described above. There can be no. Further, the raw material response characteristic correcting means 45 selects a later one of the new hydrogen response characteristic and the air response characteristic as the target response characteristic, so that only hydrogen shortage occurs in the fuel cell main body 2 or air One of the raw materials where only a shortage occurs is sufficiently supplied, but the occurrence of a situation where the other raw material is insufficient can be prevented.
[0075]
(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. The basic configuration of the fuel cell system of the fourth embodiment is the same as that of the fuel cell system 1 of the first to third embodiments, but the processing contents in the controller 50 are different from those of the respective embodiments. . Hereinafter, the processing content of the controller 50 which is a characteristic point of the fuel cell system of the fourth embodiment will be described. In addition, the same code | symbol is attached | subjected about the structure similar to each said embodiment, and detailed description is abbreviate | omitted.
[0076]
The controller 50 included in the fuel cell system according to the fourth embodiment has the same microprocessor configuration as the controller 17 included in the fuel cell system 1. In the controller 50, the CPU uses the RAM as a work area to execute a control program stored in the ROM, and as shown in FIG. A function as the raw material supply response characteristic setting means 19, a function as the target load extraction trajectory setting means 20, a function as the load current change prediction calculation means 21, a function as the voltage change prediction calculation means 22, and a target load extraction A function as the trajectory correction means 23, a function as the voltage correction amount calculation means 31, a function as the load current correction amount calculation means 32, a function as the hydrogen supply amount correction means 41, and a hydrogen supply response characteristic correction means 42 Function as the air supply amount correction means 43, function as the air supply response characteristic correction means 44, and raw material response In addition to these functions, a function as the target voltage trajectory setting means 51 and a function as the load control mode selection means 52 are realized. ing.
[0077]
The target voltage trajectory setting means 51 sets the target voltage trajectory based on the voltage correction amount calculated by the voltage correction amount calculation means 31.
[0078]
The load control mode selection means 52 selects either the target load take-out trajectory correction means 23 or the target voltage trajectory setting means 51 depending on the voltage correction amount calculated by the voltage correction amount calculation means 31. To do. Specifically, the load control mode selection unit 52 selects and executes the target voltage trajectory setting unit 51 when the voltage correction amount exceeds a predetermined value, and when the voltage correction amount does not exceed the predetermined value. Selects and executes the target load take-out trajectory correcting means 23.
[0079]
In the fuel cell system having the controller 50 as described above, when the voltage correction amount exceeds a predetermined value as a result of the processing by the controller 50, the target based on the correction amount of the load current in the second and third embodiments described above. The load trajectory is not corrected, and the operation amount of the correction operation by the hydrogen supply amount correcting means 41 and the air supply amount correcting means 43 is calculated based on the target voltage trajectory set by the target voltage trajectory setting means 51. Is called. At this time, in the hydrogen supply amount correction means 41 and the air supply amount correction means 43, the target voltage trajectory and the actual voltage of the fuel cell body 2, specifically, the voltage detected by the voltage sensor 14 are made to coincide. One or more correction operations are selected, and the operation amount is calculated.
[0080]
Here, an example of processing by the controller 50 as described above will be specifically described with reference to the flowchart of FIG.
[0081]
First, although not shown in the figure, a flag (FLAG_A) for determining whether or not this operation flow has been executed is checked. When the value of this flag is 0, the target response characteristic of the source gas is set. (Step S21). Next, a target load trajectory is set (step S22), and a target load current is calculated based on the target load trajectory (step S23). Then, using the predicted value of the target load current, a change in voltage in the fuel cell main body 2 is predicted (step S24), and it is determined whether or not this change in voltage may fall below the lower limit value (step S25). ). If the value does not fall below the lower limit, 0 is substituted into the identification variable FLAG_A (initialization) so that the process is started again from step S23 in the next control cycle (step S26), and thereafter each process is performed again. Is repeated, and a voltage correction amount that makes the voltage of the fuel cell body 2 equal to or higher than the lower limit value is calculated (step S27).
[0082]
Then, it is determined whether or not the voltage correction amount calculated in step S27 exceeds a predetermined value (step S28). When the voltage correction amount exceeds a predetermined value, first, the controller 50 functions as the load control mode selection means 52 and selects to execute the function as the target voltage trajectory setting means 51. Then, when the controller 50 functions as the target voltage trajectory setting means 51, a target voltage trajectory for returning the voltage of the fuel cell main body 2 to the lower limit value or more is set (step S29). In the present embodiment, the target voltage trajectory is calculated and set by referring to the IV characteristics of the fuel cell system shown in FIG.
[0083]
Next, the controller 50 functions as the hydrogen supply amount correction means 41 so that the target voltage trajectory set in step S29 matches the actual voltage of the fuel cell body 2 detected by the voltage sensor 14. The hydrogen flow correction operation to be executed is selected, and the operation amount in the selection operation is calculated (step S30). The correction operation is the same as the correction operation in the third embodiment. Then, based on this operation amount correction operation, the hydrogen response characteristic is corrected (step S31).
[0084]
Next, the controller 50 selects an air flow rate correction operation to be executed in order to match the target voltage trajectory with the actual voltage of the fuel cell body 2, and calculates an operation amount in the selection operation (step S32). Then, the air response characteristic is corrected based on the operation amount correction operation (step S33). Further, the response characteristic of hydrogen corrected in step 31 is compared with the response characteristic of air corrected in step S33, the slower response characteristic is selected, and the target set in step S21 is selected. The target response characteristic is corrected by replacing the response characteristic (step S34), and then 1 is substituted into the identification variable FLAG_A so that the process is started from step S23 in the next control cycle (step S35), and thereafter again. Each process is repeated.
[0085]
When the voltage correction amount does not exceed the predetermined value, first, the controller 50 functions as the load control mode selection unit 52 and selects to execute the function as the load current correction amount calculation unit 32. The controller 50 functions as the load current correction amount calculation means 32, and the load current correction amount is calculated based on the voltage correction amount calculated in step S27 (step S36). Thereafter, the controller 50 functions as the target load take-out trajectory correcting means 23 to correct the target load trajectory (step S37). Thereafter, the processing from step S30 to step S35 is executed. When the load current correction amount calculation means 32 is selected by the load control mode selection means 61, the correction executed to make the target load current and the actual load current coincide in step S30 and step S32. An operation is selected, and an operation amount in the selection operation is calculated.
[0086]
According to the fuel cell system of the fourth embodiment as described above, the shortage of raw materials of the fuel cell main body 2 can be reduced when the load transiently increases and changes. Further, when the voltage correction amount exceeds a predetermined value, that is, when the voltage drop is in a significant situation, the target voltage trajectory setting means 51 is selected to control the fuel cell main body 2 with a focus on preventing the voltage drop. Therefore, it is possible to more reliably prevent the battery itself from being damaged when the voltage of the fuel cell body 2 falls below the lower limit value.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a fuel cell system according to a first embodiment.
FIG. 2 is a functional block diagram showing each function realized by a controller of the fuel cell system according to the first embodiment.
FIG. 3 is a functional block diagram showing functions realized by a controller of a fuel cell system according to a second embodiment.
FIG. 4 is a functional block diagram showing functions realized by a controller of a fuel cell system according to a third embodiment.
FIG. 5 is a flowchart showing an example of processing by a controller of a fuel cell system according to a third embodiment.
FIG. 6 is a diagram for explaining a method of predicting a voltage change in the controller of the fuel cell system according to the third embodiment.
FIG. 7 is a diagram for explaining a method of correcting a target load trajectory in a controller of a fuel cell system according to a third embodiment.
FIG. 8 is a functional block diagram showing functions realized by a controller of a fuel cell system according to a fourth embodiment.
FIG. 9 is a flowchart showing an example of processing by a controller of a fuel cell system according to a fourth embodiment.
FIG. 10 is a diagram for explaining a method of calculating and setting a target voltage trajectory in the controller of the fuel cell system according to the fourth embodiment.
[Explanation of symbols]
1 Fuel cell system
2 Fuel cell body
4 Air supply device
7 Hydrogen supply equipment
10 Hydrogen circulation pump
11 Purge valve
13 External load
14 Voltage sensor
15 Load current sensor
17, 30, 40, 50 controller
18 Required feed flow rate calculation means
19 Raw material supply response characteristic setting means
20 Target load extraction trajectory setting means
21 Load current change prediction calculation means
22 Voltage change prediction calculation means
23 Target load extraction trajectory correction means
31 Voltage correction amount calculation means
32 Load current correction amount calculation means
41 Hydrogen supply amount correction means
42 Hydrogen supply response characteristic correction means
43 Air supply amount correction means
44 Air supply response characteristic correction means
45 Raw material response characteristic correction means
51 Target voltage trajectory setting means
52 Load control mode selection means

Claims (6)

A fuel cell body;
A hydrogen supply device for supplying hydrogen as a raw material gas to the fuel cell body;
An air supply device for supplying air as a raw material gas to the fuel cell body;
A necessary supply material flow rate calculation means for calculating a supply flow rate of the necessary material gas to the fuel cell main body based on a predetermined load current;
Raw material supply response characteristic setting means for setting a target response characteristic based on the response characteristic of each raw material gas when the actual supply flow rate increases to the required supply flow rate,
Based on the target response characteristics, target load extraction trajectory setting means for setting a trajectory for extracting the predetermined load current from the fuel cell main body,
A load current change prediction calculating means for calculating a change in the future load current based on the trajectory for taking out the predetermined load current;
Voltage change prediction calculation means for predicting a future voltage change of the fuel cell body based on the change in the future load current and the state of the fuel cell body;
A target load take-out trajectory correcting means for correcting the trajectory set by the target load take-out trajectory setting means based on the magnitude of the voltage change;
The fuel cell system, wherein the predetermined load current is extracted from the fuel cell main body in a new trajectory corrected by the target load extraction trajectory correcting means. A voltage correction amount calculating means for calculating a correction amount of the voltage of the fuel cell body with reference to the voltage change;
Load current correction amount calculating means for calculating a correction amount of the load current based on the correction amount of the voltage and the state of the fuel cell main body;
2. The fuel cell system according to claim 1, wherein the target load extraction trajectory correcting means corrects the trajectory set by the target load extraction trajectory setting means based on the correction amount of the load current. Load current detecting means for detecting a load current taken out from the fuel cell body;
At least one of the plurality of correction operations is performed so that the load current before being corrected by the calculation result of the load current correction amount calculating means matches the actual load current detected by the load current detecting means. Hydrogen supply amount correction means for selecting and calculating the operation amount to correct the hydrogen supply flow rate;
At least one of the plurality of correction operations is performed so that the load current before being corrected by the calculation result of the load current correction amount calculating means matches the actual load current detected by the load current detecting means. Air supply amount correction means for selecting and calculating the operation amount to correct the air supply flow rate ;
A raw material response characteristic for correcting a target response characteristic set by the raw material supply response characteristic setting unit based on a correction operation selected by the hydrogen supply flow rate correction unit or a correction operation selected by the air supply flow rate correction unit. The fuel cell system according to claim 2, further comprising correction means . The correction operations for correcting the hydrogen supply flow rate are the opening operation of the purge valve, the rotation speed operation of the hydrogen circulation pump and the opening operation of the hydrogen supply valve, and the correction operation for correcting the air supply flow rate is the air 4. The fuel cell system according to claim 3, wherein the rotation speed operation of the supply device and the opening operation of the air electrode pressure adjustment valve are performed. Hydrogen supply response characteristic correcting means for correcting the response characteristic of hydrogen based on the correction operation selected by the hydrogen supply amount correcting means;
An air supply response characteristic correcting means for correcting an air response characteristic based on the correction operation selected by the air supply amount correcting means ,
The raw material response characteristic correction means is slower among the hydrogen response characteristic corrected by the hydrogen supply response characteristic correction means and the air response characteristic corrected by the air supply response characteristic correction means. 4. The fuel cell system according to claim 3 , wherein a response characteristic is selected, and the target response characteristic set by the raw material supply response characteristic setting means is corrected to the selected response characteristic . Voltage detection means for detecting the voltage of the fuel cell body;
Target voltage trajectory setting means for setting a target voltage trajectory based on the voltage correction amount calculated by the voltage correction amount calculating means;
Load control mode selection means for selecting whether to execute the target load take-out trajectory correction means or the target voltage trajectory setting means according to the voltage correction amount;
When the correction amount of the voltage exceeds a predetermined value, the target voltage trajectory setting means is selected by the load control mode selection means, and the target voltage trajectory and the actual voltage detected by the voltage detection means coincide with each other. 4. The fuel cell system according to claim 3, wherein the operation amount of the correction operation is calculated in the hydrogen supply amount correction means and the air supply amount correction means.

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