JP4604389B2 - Fuel cell system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel cell system including a fuel cell that generates electric energy by a chemical reaction between hydrogen and oxygen, and is effective when applied to a moving body such as a vehicle, a ship, and a portable generator.
[0002]
[Prior art]
For example, in a fuel cell system mounted on a vehicle, the load power required for vehicle travel changes abruptly according to the driving pattern of the driver, such as acceleration / deceleration, so the power generated by the fuel cell also depends on the load power. System configuration.
[0003]
However, since the response speed of the flow control of hydrogen and air as fuel is slow, it is difficult to make the generated power of the fuel cell correspond to the load power of the vehicle that changes significantly. For this reason, in an in-vehicle fuel cell system, a secondary battery is connected to the fuel cell via a voltage converter (DC / DC converter), and the secondary battery temporarily bears a change in power that cannot be caught by the fuel cell. System configuration.
[0004]
Control of the power generated by the fuel cell in such an on-vehicle fuel cell system is necessary to maintain the power consumption of the high voltage auxiliary equipment such as inverter power and fuel supply pumps, and the capacity of the secondary battery at a predetermined value. It must be controlled to make up for all of the required charge / discharge power of the secondary battery and the conversion loss power of the voltage converter.
[0005]
As an example of controlling such a fuel cell system, for example, there is a control method described in Japanese Patent Laid-Open No. 2000-12059. In this method, the required output of the inverter is calculated from the accelerator opening, and the fuel cell control unit calculates and controls the generated power of the fuel cell from the output current / output voltage characteristics derived based on the detected gas amount. . In this method, the fuel cell always generates power at the most efficient point with respect to the amount of gas and supplies power to the output of the inverter, while the secondary battery supplements the power that causes excess or deficiency. ing.
[0006]
[Problems to be solved by the invention]
In the fuel cell system, the total power consumption of the fuel cell system is calculated and used as the target power generation output of the fuel cell. In calculating the total power consumption, it is necessary to consider the conversion efficiency f of the voltage converter. This conversion efficiency f takes into account the power consumption of the inverter, high-voltage auxiliary equipment, the required charge / discharge power of the secondary battery, etc. It is calculated.
[0007]
The power generation output of the fuel cell needs to match the actual total power consumption of the power consuming device. However, power consumption such as power consumption devices such as inverters, high-voltage auxiliary devices, and required charge / discharge power of secondary batteries is detected for each device. For this reason, there is a problem that the total power consumption and the generated power of the fuel cell do not match due to the influence of the detection error of the power consumption and the wiring resistance between the devices for each device. In addition, since the conversion efficiency f of the voltage converter also changes depending on the temperature, the magnitude of current, and the like, there is a problem that the calculated value of the total power consumption does not match the actual value when the conversion efficiency value is used.
[0008]
In such a case, as the result, the charge / discharge power of the secondary battery that is controlled according to the eventuality is used, so that the battery capacity changes significantly over time, and in the worst case, there is a possibility that the vehicle cannot run. .
[0009]
The present invention has been made in view of the above points, and an object thereof is to provide a fuel cell system capable of calculating a target generated power of a fuel cell without being affected by a power consumption error generated for each power consuming device. .
[0010]
[Means for Solving the Problems]
In order to achieve the above object, according to the first aspect of the present invention, a fuel cell (10) that generates electrical energy by a chemical reaction between hydrogen and oxygen and a fuel cell (10) connected in parallel and chargeable / dischargeable. A secondary battery (17), a voltage converter (16) provided between the fuel cell (10) and the secondary battery (17) for adjusting the output voltage of the fuel cell (10), and a voltage converter A plurality of current sensors (20 to 22) for detecting the current value on the input side and the current value on the output side of (16), and the voltage value on the input side and the voltage value on the output side of the voltage converter (16) are detected. A pair of voltage sensors (30, 31) , an input side current value and an output side current value of the voltage converter (16) detected by the current sensors (20 to 22), and a voltage sensor (30, 31). Input side voltage value and output side voltage of the voltage converter (16) The target for calculating the target generated power of the fuel cell (10) using the conversion efficiency calculation means for calculating the conversion efficiency of the voltage converter (16) based on the value and the conversion efficiency of the voltage converter (16). The plurality of current sensors (20 to 22) includes: generated power calculation means; and output voltage control means for controlling the output voltage of the fuel cell (10) by the voltage converter (16) based on the target generated power. The output current of the fuel cell (10) is provided at a location where the output current is distributed, the plurality of voltage sensors (30, 31) are provided at locations where the potentials are equipotential, and the output voltage control means is the fuel cell (10 ), The output voltage of the fuel cell (10) is controlled so as to be the power immediately before the sudden change .
[0011]
Thereby, when calculating the conversion efficiency of a voltage converter (16), the power consumption error for every apparatus and the power consumption error by wiring resistance can be disregarded. By using the conversion efficiency of the voltage converter (16) calculated in this way, the target generated power of the fuel cell (10) can be calculated more accurately.
[0012]
In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment to which the present invention is applied will be described with reference to FIGS. In this embodiment, the fuel cell system of the present invention is applied to an electric vehicle.
[0014]
FIG. 1 shows the overall configuration of the fuel cell system of the present embodiment. As shown in FIG. 1, the fuel cell system of the present embodiment includes a fuel cell (FC stack) 10, a hydrogen supply device 11, an air supply device 12, an inverter 14, a DC / DC converter (voltage adjusting means) 16, 2. A secondary battery 17, a high voltage auxiliary machine 19 and the like are provided.
[0015]
The fuel cell (FC stack) 10 generates electric power by utilizing an electrochemical reaction between hydrogen and oxygen. In this embodiment, a solid polymer electrolyte fuel cell is used as the fuel cell 10, and a plurality of single cells serving as basic units are stacked. In the fuel cell 10, when hydrogen and air (oxygen) are supplied, the following electrochemical reaction between hydrogen and oxygen occurs to generate electric energy.
(Hydrogen electrode side) H ₂ → 2H ⁺ + 2e ⁻
(Oxygen electrode side) 2H ⁺ + 1 / 2O ₂ + 2e ⁻ → H ₂ O
The fuel cell system includes a hydrogen supply device 11 for supplying hydrogen to the hydrogen electrode (negative electrode) side of the fuel cell 10 and air for supplying air (oxygen) to the oxygen electrode (positive electrode) side of the fuel cell 10. A supply device 12 is provided. As the hydrogen supply device 11, for example, a reforming device that generates hydrogen by a reforming reaction, or a hydrogen tank that stores pure hydrogen by incorporating a hydrogen storage material such as a hydrogen storage alloy can be used. As the air supply device 12, for example, a compressor or a blower can be used.
[0016]
An inverter 14 is connected to the fuel cell 10 via a diode 13. The diode 13 flows current only from the fuel cell 10 toward the inverter 14. The inverter 14 is configured to convert the direct current supplied from the fuel cell 10 into an alternating current and supply it to the traveling motor 15 to drive the motor 15.
[0017]
A rechargeable secondary battery (battery) 17 is connected in parallel to the fuel cell 10 via a DC / DC converter (voltage adjusting means) 16. The DC / DC converter 16 is configured to convert a voltage between the fuel cell 10 and the secondary battery 17. In the DC / DC converter 16, power loss occurs during voltage conversion. The surplus power generated by the fuel cell 10 is charged to the secondary battery 17, and when the output of the fuel cell 10 is insufficient, the secondary battery 17 supplies the insufficient power.
[0018]
When the FC stack 10 and the secondary battery 17 are connected in parallel to supply power to the inverter 14, the potentials of both need to be equal. Therefore, in the present embodiment, the DC / DC converter 24 performs voltage conversion so that the voltages of the FC stack 10 and the secondary battery 17 are the same. With such a configuration, the FC stack 10 and the secondary battery 17 can share power supply to the inverter 14.
[0019]
The secondary battery 17 is provided with an SOC detection device 18 that detects the remaining battery capacity SOC of the secondary battery 17. The battery capacity SOC is detected by a known method. For example, there are a method of obtaining the change in capacity with respect to the initial capacity of the secondary battery 17 by integrating the charge / discharge current value and time, or a method of obtaining from the VI characteristic of the secondary battery 17.
[0020]
FIG. 2 is map data representing the target power Pchg of the charge / discharge power of the secondary battery 17 with respect to the battery capacity SOC of the secondary battery 17. As shown in FIG. 2, the charge / discharge target power Pchg of the secondary battery 17 is set in advance so as to change according to the battery capacity SOC of the secondary battery 17. In the present embodiment, the charge / discharge target power Pchg is set so that the battery capacity of the secondary battery 17 is 60%, for example. Therefore, when the battery capacity SOC is 60% or more, the target charge / discharge power Pchg of the secondary battery 17 is set to a negative value. Conversely, when the battery capacity SOC is less than 60%, the target charge / discharge power Pchg of the secondary battery 17 is set to a positive value.
[0021]
Further, a high voltage auxiliary machine 19 is connected to the fuel cell 10 via a DC / DC converter 16. The high voltage auxiliary machinery 19 is a device that consumes electric power, such as the air supply compressor 11. Since it is necessary to vary the fuel supply amount according to the inverter required power, the power consumption PHk of the auxiliary machinery 19 is a value that varies according to the inverter required power.
[0022]
The fuel cell system of this embodiment is provided with current sensors 20 to 23 and voltage sensors 30 and 31. The current sensors 20 to 23 are arranged at a position where the current branches on the wiring connecting the devices, one less than the number of the branched wirings. The current in the direction in which the current sensors 20 to 23 are not provided can be calculated by the other two current sensors.
[0023]
The first current sensor 20 detects the output current value IFC of the fuel cell 10, the second current sensor 21 detects the current value IM flowing through the inverter 14, and the third current sensor 22 detects the current value flowing from the DC / DC converter 16. IDC is detected, and the current value Ibat flowing through the secondary battery 17 is detected by the fourth current sensor 23. The value of the current flowing through the DC / DC converter 16 can be obtained by (IFC-IM), and the value of the current flowing through the high voltage auxiliary machinery 19 can be obtained by (IDC-IBat).
[0024]
Further, the voltage sensors 30 and 31 are arranged one by one at a location where the potential is equal when the wiring resistance on the input side and output side of the DC / DC converter 16 is ignored with the DC / DC converter 16 interposed therebetween. . The voltage value VFC on the fuel cell 10 side is detected by the first voltage sensor, and the voltage value VBat on the secondary battery 17 side is detected by the second voltage sensor.
[0025]
FIG. 3 shows the control device 40 of the fuel cell system of the present embodiment. The fuel cell system of this embodiment is provided with a control device 40 shown in FIG. The control device 40 is configured to receive sensor signals from various sensors and output control signals to each device such as the DC / DC converter 16.
[0026]
Next, the operation of the fuel cell system according to the present embodiment will be described with reference to FIGS. FIG. 4 is a flowchart showing the operation of the fuel cell system. The following control is repeatedly performed at a predetermined cycle.
[0027]
First, the travel target power FPPower is calculated based on a signal such as the accelerator opening of the vehicle driver (step S10). This travel target power FPpower becomes the required output (target output) PMo of the inverter 14. Next, current values IFC, IM, IDC and voltage values VFC, VBat of each part of the fuel cell system are detected by the current sensors 20-23 and the voltage sensors 30, 31 (step S11).
[0028]
Next, the SOC detection device 18 detects the battery capacity SOC of the secondary battery 17 (step S12), and obtains the target charge / discharge power Pchg of the secondary battery 17 based on the map of FIG. 2 (step S13).
[0029]
Next, power distribution calculation is performed (step S14). The power distribution calculation is performed as shown in FIG. The actual power flowing through the fuel cell 10, the inverter 14, the secondary battery 17, and the high-voltage auxiliary machinery 19 is the fuel cell power Pfc = IFC × VFC, the inverter power PM = IM × VFC, and the secondary battery charge / discharge. The electric power Pbat = IBat × Vbat and the auxiliary power PHk = (IDC−IBat) × Vbat can be obtained.
[0030]
The conversion efficiency (power efficiency) f of the DC / DC converter 16 is calculated from the input side current value, the output side current value, the input side voltage value, and the output side voltage value of the DC / DC converter 16 by f = (Vbat × IDC) / (VFC × (IFC-IM)).
[0031]
The travel target power FPpower obtained in step S10 is set as the inverter target power PMo. The target power PHko of the auxiliary equipment 19 necessary for supplying the fuel cell 10 with the air flow rate and the hydrogen flow rate required for the fuel cell 10 to output the inverter target power PMo is obtained. The auxiliary machine target power PHko is a value determined by the inverter target power PMo.
[0032]
The target generated power Pfco of the fuel cell 10 is calculated from the inverter target power PMo, which is a calculated value, the auxiliary machinery target power PHko, the secondary battery target charge / discharge power Pchg, and the conversion efficiency f of the DC / DC converter 16 which is an actually measured value. , Pfco = PMo + f (PHko + Pchg).
[0033]
Next, power generation control of the fuel cell 10 is performed based on the power distribution calculation calculated in step S14 (step S15). Specifically, the amount of supplied gas is controlled by the gas supply devices 11 and 12. Further, the output voltage of the fuel cell 10 is controlled by the DC / DC converter 16.
[0034]
The output voltage control of the fuel cell 10 by the DC / DC converter 16 will be described based on the output characteristic diagram of the fuel cell 10 shown in FIG. In FIG. 6, g1 to g3 are output characteristics of the fuel cell 10 when the hydrogen supply amount and the air supply amount to the fuel cell 10 are changed. g1 has the smallest supply amount, and g3 has the largest supply amount. As shown in FIG. 6, the output characteristics abruptly change at g1 at point A, g2 at point B, and g3 at point C.
[0035]
For this reason, in each gas supply amount, most power can be extracted from the fuel cell 10 most efficiently by generating power at points A to C immediately before the output characteristics suddenly change. Therefore, the output voltage VFC of the fuel cell 10 is controlled by the DC / DC converter 16 so that the power can be extracted from the fuel cell 10 most efficiently at each gas supply amount.
[0036]
As described above, the current sensors 20 to 23 are provided at locations where the generated power of the fuel cell 10 is distributed, and the voltage sensors 30 and 31 are provided at locations where the voltages are equipotential, thereby converting the DC / DC converter 16. When calculating the efficiency f, it is possible to ignore power consumption errors for each device and power consumption errors due to wiring resistance. As a result, the target generated power Pfco of the fuel cell 10 can be calculated more accurately.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of a fuel cell system according to the embodiment.
FIG. 2 is a characteristic diagram showing map data in which a battery capacity SOC of a secondary battery and a target charge / discharge power Pchg are associated with each other.
FIG. 3 is a control block diagram of the fuel cell system of the embodiment.
FIG. 4 is a flowchart showing the operation of the fuel cell system of the embodiment.
FIG. 5 is a block diagram showing power distribution calculation of the fuel cell system of the embodiment.
FIG. 6 is a characteristic diagram showing output characteristics of a fuel cell.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Fuel cell (FC stack), 11 ... Hydrogen supply apparatus, 12 ... Air supply apparatus, 14 ... Inverter, 16 ... DC / DC converter (voltage converter), 17 ... Secondary battery, 19 ... Auxiliaries, 20 -23 current sensor, 30, 31 ... voltage sensor.

Claims (1)

A fuel cell (10) that generates electrical energy by a chemical reaction between hydrogen and oxygen;
A secondary battery (17) connected in parallel with the fuel cell (10) and capable of being charged and discharged;
A voltage converter (16) provided between the fuel cell (10) and the secondary battery (17) for adjusting an output voltage of the fuel cell (10);
A plurality of current sensors (20 to 22) for detecting the current value on the input side and the current value on the output side of the voltage converter (16);
A pair of voltage sensors (30, 31) for detecting the voltage value on the input side and the voltage value on the output side of the voltage converter (16) ;
The input side current value and output side current value of the voltage converter (16) detected by the current sensor (20-22), and the voltage converter (16) detected by the voltage sensor (30, 31). Conversion efficiency calculating means for calculating the conversion efficiency of the voltage converter (16) based on the input side voltage value and the output side voltage value of
Target generated power calculation means for calculating target generated power of the fuel cell (10) using the conversion efficiency of the voltage converter (16);
Output voltage control means for controlling the output voltage of the fuel cell (10) by the voltage converter (16) based on the target generated power,
The plurality of current sensors (20 to 22) are respectively provided at locations where the output current of the fuel cell (10) is distributed,
The plurality of voltage sensors (30, 31) are respectively provided at equipotential locations,
The fuel cell system, wherein the output voltage control means controls the output voltage of the fuel cell (10) so that the power immediately before the output characteristic of the fuel cell (10) suddenly changes .

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